Phytochrome evolution: Phytochrome genes in ferns and mosses

We have isolated phytochrome genes from the moss Physcomitrella , the fern Psilotum and PCR-generated phytochrome sequences from a few other ferns. The phytochrome gene of the moss Physcomitrella turned out not to contain the aberrant C-terminal third of the phytochrome from the moss Ceratodon , but the transmitter module-like sequences found in other phytochromes. A series of different phytochrome genes was detected in Psilotum . Differences between the amino acid sequences derived from them ranged from about 5 to more than 22%. Some of these genes are likely pseudogenes. Analysis by phylogenetic tree constructions revealed that higher and lower plant phytochromes evolved with different velocities. Lower plant phytochromes form a separate family characterized by a high degree of similarity. The amino acid differences between phytochrome types detected in a single species of higher plants are about two-fold higher than the differences between phytochromes of species of lower plants belonging to different divisions ( Physcomitrella and Selaginella ). Future studies on phytochrome sequences may eventually also throw light on the significance of Psilotum in the evolution of vascular plants.     

Cryptogam phytochromes

Phytochrome responses in cryptogams are well characterized. However, the properties of cryptogam phytochromes are not well understood, because of the difficulty in obtaining suitable material. Recent advances in molecular biology offer the possibility of studying cryptogam phytochromes at the molecular level. The functional domains in cryptogam phytochromes have been predicted from the homology of the deduced amino acid sequences to known sequences of different functional proteins. Cryptogam phytochrome gene families are highly variable in size and composition. The most structurally unusual cryptogam phytochrome, found in the moss Ceratodon and the fern Adiantum, has a protein kinase catalytic domain in the C-terminal half, although the N-terminal half is homologous to conventional phytochromes. In conventional phytochrome, modules homologous to the bacterial two-component (transmitter) protein kinase have also been found in the C-terminal ends. While phytochromes lack membrane-spanning sequences, some types may have microtubule attachment sequences. The relationship of these to dichroic phytochrome is discussed. Phytochrome mRNA and proteins are also discussed, as well as the use of mutants in elucidating signal transduction pathways.     

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.     

Phytochrome gene diversity

The structures and functions of the phytochrome apoprotein genes (the PHY genes), their diversity across the plant kingdom, and their evolution are central concerns in the study of red-light sensing in plants. We summarize here recent advances in two areas relating to these topics: (1) the characteristics of the PHY gene family in Arabidopsis thaliana, the higher plant species for which the most extensive information on these genes is available, and (2) the similarity relationships, phylogeny, and evolutionary implications of PHY gene sequences and partial sequences which have been described from various plants. Together, these two areas of study, one directed at understanding in detail the phytochromes present in a single species and the other directed at a much broader understanding of PHY gene relatedness and distribution, are producing an increasingly clear picture of the diversity and evolution of plant red-light photoreceptors. Moreover, they suggest that the complexity of the phytochrome family has increased as land plants have evolved novel morphologies.     

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。     

Cross-reactivity of monoclonal antibodies against phytochrome from Zea and Avena

The cross-reactivity of diverse monoclonal antibodies against phytochrome from Zea and Avena was tested by enzyme-linked immunosorbentassay (ELISA) and by immunoblotting. About 40 antibodies were selected by means of nondenatured phytochrome; all of them reacted with sodium dodecyl sulfate denatured homologous antigen on immunoblots. The epitopes for 14 antibodies (4 raised against Avena and 10 against Zea phytochrome) were localized in 6 regions of the phytochrome molecule by means of Western blot analysis of proteolytic fragments of known localization. Results of studies on the inhibition of antibody binding by other antibodies were largely compatible with these latter findings. Except in a few cases, inhibition occurred when antibodies were located on the same or a closely adjacent region. As demonstrated by 16 species, cross-reactivity with phytochromes from other Poaceae was high. Greater losses in cross-reactivity were observed only with antibodies recognizing an epitope in the vicinity of the carboxyl terminus of 118-kg · mol^-1 phytochrome. Cross-reactivity with phytochrome from dicotyledons was restricted to a few antibodies. However, phytochrome(s) from plants illuminated for 24 h or more could be detected. One of the antibodies that recognized phytochrome from dicotyledons was also found to recognize phytochrome or a protein of 120–125 kg·mol^-1 from several ferns, a liverwort and mosses. This antibody (Z-3B1), which was localized within a 23.5-kg·mol^-1 section of Avena phytochrome (Grimm et al., 1986, Z. Naturforsch. 41c, 993), seems to be the first antibody raised against phytochrome from a monocotyledon with such a wide range of reactivity. Even though epitopes were recognized on different phytochromes, the strength of antibody binding indicated that these epitopes are not necessarily wholly identical.Abbreviations ELISA enzyme-linked immunosorbent assay - McAb monoclonal antibody - PBS phosphate-buffered saline - Pfr (Pr) far-red-absorbing (red-absorbing) form of phytochrome - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Spatial distribution of phytochromes

Phytochromes are chromoproteins which mediate several light responses in plants. Phytochrome proteins are encoded by a gene family which is currently being characterized in several plant species. Analysis of type-specific mutants of two well-characterized members of the family, PhyA and PhyB, indicates that these proteins have distinct functions. Much remains to be learned about the mechanisms by which the phytochromes carry out their distinct and diverse functions. It is hoped that information concerning the localization of phytochromes, at the whole plant and subcellular levels, will aid in elucidating the mechanism of phytochrome function. This review, which summarizes information about phytochrome distribution, has an emphasis on recent reports in which the molecular species of phytochrome are differentiated. However, classical data are also included and reinterpreted using knowledge of the phytochrome family.     

An Evolutionarily Conserved Signaling Mechanism Mediates Far-Red Light Responses in Land Plants

Phytochromes are plant photoreceptors important for development and adaptation to the environment. Phytochrome A (PHYA) is essential for the far-red (FR) high-irradiance responses (HIRs), which are of particular ecological relevance as they enable plants to establish under shade conditions. PHYA and HIRs have been considered unique to seed plants because the divergence of seed plants and cryptogams (e.g., ferns and mosses) preceded the evolution of PHYA. Seed plant phytochromes translocate into the nucleus and regulate gene expression. By contrast, there has been little evidence of a nuclear localization and function of cryptogam phytochromes. Here, we identified responses to FR light in cryptogams, which are highly reminiscent of PHYA signaling in seed plants. In the moss Physcomitrella patens and the fern Adiantum capillus-veneris, phytochromes accumulate in the nucleus in response to light. Although P. patens phytochromes evolved independently of PHYA, we have found that one clade of P. patens phytochromes exhibits the molecular properties of PHYA. We suggest that HIR-like responses had evolved in the last common ancestor of modern seed plants and cryptogams and that HIR signaling is more ancient than PHYA. Thus, other phytochromes in seed plants may have lost the capacity to mediate HIRs during evolution, rather than that PHYA acquired it.     

Avena sativa L. contains three phytochromes,only one of which is abundant in etiolated tissue

Phytochrome from leaves of light-grown oat (Avena sativa L. cv. Garry) plants is characterized with newly generated monoclonal antibodies (MAbs) directed to it. The results indicate that there are at least two phytochromes in green oat leaves, each of which differs from the phytochrome that is most abundant in etiolated oat tissue. When analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) with reference to 124-kilodalton (kDa) phytochrome from etiolated oats, the two phytochromes from green oats have monomer sizes of 123 of 125 kDa. Immunoblot analysis of SDS, sample buffer extracts of lyophilized, green oat leaves indicates that neither the 125-kDa nor the 123-kDa polypeptide is a degradation product arising after tissue homogenization. Of the two, the 123-kDa phytochrome appears to be the predominant species in light-grown oat leaves. During SDS-PAGE in the presence of 1 mM Zn²⁺, 123-kDa phytochrome undergoes a mobility shift corresponding to an apparent mass increase of 2 kDa. In contrast, the electrophoretic mobility of 125-kDa phytochrome is unaffected by added Zn²⁺. Some MAbs that recognize 123-kDa phytochrome fail to recognize 125-kDa phytochrome and vice versa, indicating that these two phytochromes are not only immunochemically distinct from 124-kDa phytochrome, but also from each other. It is evident, therefore, that there are at least three phytochromes in an oat plant: 124-kDa phytochrome, which is most abundant in etiolated tissue, plus 123-and 125-kDa phytochromes, which predominate in light-grown tissue.Abbreviations Da Dalton - HA hydroxyapatite - MAb monoclonal antibody - PAb polyclonal antibody preparation - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulfate This research was supported by the U.S. Department of Energy (contract DE-AC-09-81SR10925 to L.H.P.). We thank Dr. Alan Jones, Department of Biology, University of North Carolina, Chapel Hill, USA, for kindly providing rabbit antiserum 4032, and Mrs. Donna Tucker and Mrs. Danielle Neal for their technical assistance.     

Photomorphogenic mutants of tomato

Photomorphogenesis of tomato (Lycopersicon esculentum Mill.) is being studied with the aid of mutants which are modified either in their photoreceptor composition or in their signal transduction chain(s). Phytochrome chromophore mutants, presumably deficient in all phytochromes, and mutants specifically deficient in phytochrome A (phy A) or B1 (phyB1) have been used to study the roles played by phytochromes in photomorphogenesis. In addition, other mutants, including transgenic lines overproducing phyA, exhibit exaggerated photomorphogenesis. Studies using these mutants are reviewed, with emphasis being placed on anthocyanin biosynthesis and plastid development as model systems for the dissection of the complex interactions between photoreceptors and to elucidate the nature of photoreceptor transduction chains. Recently, new mutants have been isolated by screening in a phyA, phyB1-deficient background. The novel phenotypes selected are candidates for mutants in additional photoreceptors or their transduction chains.     

Roles of different phytochromes in Arabidopsis photomorphogenesis

The red/far-red light-absorbing phytochromes play fundamental roles in photoperception of the light environment and the subsequent adaptation of plant growth and development. Higher plants possess multiple, discrete phytochromes, the apoproteins of which are the products of a family of divergent (PHY) genes. Arabidopsis thaliana has at least five PHY genes, encoding the apoproteins of phytochromes A-E. Through the analysis of mutants that are deficient in phytochrome A or B and the corresponding double mutant, it is becoming clear that these phytochromes perform both discrete and overlapping roles throughout plant development. Through analysis of the phyA phyB double mutant, it has been possible to define several responses that are mediated by other members of the phytochrome family. This article reviews some of the recent progress in the study of phytochrome-deficient mutants of the model plant Arabidopsis thaliana.     

Bacteriophytochromes: new tools for understanding phytochrome signal transduction

The recent discovery of phytochrome-like photoreceptors, collectively called bacteriophytochromes, in a number of bacteria has greatly expanded our understanding of the origins and modes of action of phytochromes in higher plants. These primitive receptors contain an N-terminal domain homologous to the chromophore-binding pocket of phytochromes, and like phytochromes, they bind a variety of bilins to generate photochromic holoproteins. Following the chromophore pocket is a domain similar to two-component histidine kinases, suggesting that these bacterial photoreceptors function in phosphorelay cascades that respond to the light environment. Their organization and distribution support the views that higher-plant phytochromes evolved from a cyanobacterial precursor and that they act as light-regulated kinases. With the ability to exploit bacterial genetics, these bacteriophytochromes now offer simple models to help unravel the biochemical and biophysical events that initiate phytochrome signal transmission.     

Large-scale partial purification of phytochrome from green leaves of Avena sativa L.

Phytochrome from 10 or 11-d-old oat (Avena sativa L. cv. Garry) leaves, which were harvested just prior to sunset from plants grown in a greenhouse in the absence of supplemental illumination, was purified an estimated 250-fold by sequential poly(ethylenimine) and ammonium-sulfate fractionations, followed by linear-gradient hydroxyapatite chromatography. Compared to earlier protocols, the one presented here is substantially more rapid, provides improved yield and purity, can be used with larger quantities of tissue, and eliminates an apparently immunodominant contaminant with a molecular mass of about 115 kDa (kilodalton). Phytochrome obtained by this procedure has an apparent monomer size of 123 kDa as evaluated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and is estimated to be 0.6% pure. This purity permitted spectral analysis at wavelengths below 500 nm, in which region phytochromes from green and etiolated oat shoots do not differ markedly, as they do at longer wavelengths.Abbreviations Da Dalton - HA hydroxyapatite - Pfr, Pr farredand red-absorbing form of phytochrome, respectively - SDS sodium dodecyl sulfate This research was supported by the U.S. Department of Energy (contract DE-AC-09-81SR10925 to L.H.P.). The excellent technical assistance of Mrs. Donna Tucker and Mrs. Danielle Neal is gratefully acknowledged.     

Nucleo-cytoplasmic partitioning of the plant photoreceptors phytochromes

Phytochromes in harmony with blue light photoreceptors play a major role in controlling plant growth and development from germination to seed maturation. Light absorption by phytochromes triggers a signaling cascade, phototransduction, which culminates in regulated gene expression. A major regulatory step at the cellular level, which affects specificities of light-induced physiological responses, seems to be the light-quality and light-quantity dependent nuclear import of the phytochromes themselves. The correlations found between the nuclear import of phytochromes (phyA and phyB) and various physiological responses regulated by these photoreceptors provides strong support for this hypothesis.     

Carbohydrate levels among winter wheat cultivars varying in freezing tolerance and snow mold resistance during autumn and winter

The LT₅₀ values and soluble carbohydrate levels in wheat ( Triticum aestivum L.) crowns and leaves were monitored throughout autumn and winter in cultivars varying in freezing tolerance and snow mold resistance during 1993/1994 and 1994/1995 in the field at Sapporo, Japan. During the first stage of hardening, from sowing to mid‐November, the pattern of accumulation of mono‐ and disaccharides was similar for all cultivars. During the second stage of cold hardening, from mid‐November to mid‐December, the greatest accumulation of mono‐ and disaccharides, without a corresponding increase in fructan, was observed among the freezing‐tolerant cultivars; and levels of simple saccharides rapidly decreased under snow cover. Conversely, levels of mono‐ and disaccharides in snow mold‐resistant cultivars were less than 70% of those in freezing‐tolerant cultivars before snow cover and maintained low levels throughout winter, while polysaccharide levels in snow mold‐resistant cultivars were about 120% of those in freezing‐tolerant cultivars in December. Sugar metabolism during the winter was examined using 18 cultivars in 1994/1995. LT₅₀ values were correlated to the greatest extent with total mono‐ and disaccharide and fructan content among wheat cultivars excluding snow mold‐resistant cultivars in December. Snow mold‐resistant cultivars tended to metabolize carbohydrates more slowly until the end of the snow cover period. This result suggested that the enzymatic metabolism of the synthesis of sugars and the conversion of fructan to cryoprotective sugars in response to low temperatures, especially subzero ones, might be different between the two contrasting types in resistance to winter stress.