The anatomy of phytochrome,a unique photoreceptor in plants

Red and far-red light control of plant growth and development is mediated by the photoreceptor phytochrome. The way plants utilize red and far-red light is unique in nature, as are the molecular properties of phytochrome, the molecule that provides the mechanistic basis for this type of light perception. Much of what we know about how plants perceive red lights has come from research on the structure and function of this photoreceptor. This review discusses the main structural features of phytochrome and some new ideas concerning the relationship between phytochrome structure and function. We propose that phytochrome functions as a dimer and that receptor recognition of phytochrome depends on its gross conformation. We also describe a conserved amino acid repeat within the phytochrome molecule and propose that this repeat is important for dimerization and/or phototransformation.     

Synthesis of phytochrome apoprotein and chromophore are not coupled obligatorily

G Gardner and HL Gorton (1985 Plant Physiol 77: 540) demonstrated that gabaculine (5-amino-1,3-cyclohexadienylcarboxylic acid) inhibits the initial synthesis and resynthesis of spectrophotometrically detectable phytochrome in pea, maize, and oat. We show that the level of immuno-detectable phytochrome in pea is unaffected by the presence of gabaculine at a concentration that reduces spectrophotometrically detectable phytochrome up to 10-fold. This result indicates that gabaculine inhibits chromophore synthesis without affecting phytochrome apoprotein synthesis and that chromophore-less phytochrome is stable in the cell.     

Phytochrome immunoaffinity purification

We have developed a phytochrome immunoaffinity purification procedure that yields undegraded oat (Avena sativa L., cv. Garry) phytochrome of greater than 98% purity within 2 hours when starting with a brushite-purified preparation. Immunoaffinity-purified phytochrome, except for its greater purity, is indistinguishable from conventionally purified phytochrome by gel exclusion chromatography, isoelectric focusing, and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. We have also used the immunoaffinity technique to purify phytochrome from crude oat extracts, and from brushite-purified pea (Pisum sativum L., cv. Alaska) and rye (Secale cereale L., cv. Balbo) preparations.     

Overexpression of Phytochrome B Induces a Short Hypocotyl Phenotype in Transgenic Arabidopsis

The photoreceptor phytochrome is encoded by a small multigene family in higher plants. phyA encodes the well-characterized etiolated-tissue phytochrome. The product of the phyB gene, which has properties resembling those of "green tissue" phytochrome, is as yet poorly characterized. We have developed a phytochrome B overexpression system for analysis of the structure and function of this protein. Using newly generated polyclonal and monoclonal antibodies that are selective for phytochrome B, we have demonstrated high levels of expression of full-length rice and Arabidopsis phytochrome B under the control of the cauliflower mosaic virus 35S promoter in transgenic Arabidopsis. The overexpressed phytochrome is spectrally active, undergoes red/far-red-light-dependent conformational changes, is synthesized in its inactive red light-absorbing form, and is stable in the light. Overexpression of phytochrome B is tightly correlated with a short hypocotyl phenotype in transgenic seedlings. This phenotype is strictly light dependent, thus providing direct evidence that phytochrome B is a biologically functional photoreceptor. Based on similarities to phenotypes obtained by overexpression of phytochrome A, it appears that phytochromes A and B can control similar responses in the plant.     

Spore germination and phytochrome biosynthesis in the fern Lygodium japonicum as affected by gabaculine and cycloheximide

We investigated whether the gradual increase in phytochrome content in the fern Lygodium japonicum (Thunb.) Sw. during dark imbibition results from hydration or from biosynthesis of phytochrome. Addition of gabaculine or cycloheximide to the culture medium caused inhibitions of both red light-induced spore germination and of the appearance of phytochrome in the spores. Fifty percent inhibition of both red light-induced germination and of the appearance of phytochrome in the spores occurred at ca 10⁻7 M cycloheximide. Red light-induced germination and phytochrome appearance were markedly inhibited by 10⁻4 M and completely by 10⁻3 M gabaculine, but germination induced by gibberellic acid was unaffected. Phytochrome was not detected in spores after forced hydration. These results suggest that the increase in phytochrome during imbibition was mainly due to de novo synthesis of the phytochrome apoprotein and to synthesis of the chromophore and/or proteins required for phytochrome formation, rather than to hydration of preexisting phytochrome molecules.     

Changes in the Content of Phytochrome I and II Apoproteins in Embryonic Axes of Pea Seeds during Imbibition

The contents of phytochrome I and II in crude extracts fromembryonic axes of Pisum sativum cv. Alaska seeds were immunochemicallydetermined using purified pea phytochrome I and II as standards.We have produced and used three different types of mouse monoclonalanti-pea phytochrome antibodies (mAP) such as one reacting preferentiallywith phytochrome I, one with phytochrome II, and one with bothI and II. Phytochrome II was separated from I in the samplesusing immobilized column chromatography with mAPl. The amountsof two phytochrome species were quantitatively measured withwestern blotting and ELISA. Ca. 0.2 µg /axis of phytochromeI and ca. 0.05 µg /axis of phytochrome II were detectedby ELISA after imbibition for 12 h in the dark, though smallamounts of both were detected in dry axes. Ca. 0.05 µg/axis each of phytochrome I and II were detected by ELISA afterimbibition for 12 h in the light, and the results were confirmedby western blotting. This study showed that phytochrome II isnot green-tissue-specific, being also found in dark-imbibedembryonic axes, and that although light significantly lowersthe content of phytochrome I in the axis, it does not significantlyaffect that of phytochrome II. (Received June 10, 1987; Accepted August 27, 1987)     

The interaction of light and abscisic acid in the regulation of plant gene expression.

Extended dark treatments of light-grown plants of both Lemna gibba and Arabidopsis thaliana resulted in substantial increases in abscisic acid (ABA) concentrations. The concentration of ABA could be negatively regulated by phytochrome action in Lemna. As has been noted in other species, ABA treatment reduced Lemna rbcS and Lhcb RNA levels, which are positively regulated by phytochrome in many species. In view of these observations, the possibility that phytochrome effects on gene expression may be mediated primarily by changes in ABA was tested using a transient assay in intact plants. The phytochrome responsiveness of the Lemna Lhcb2*1 promoter was still apparent in the presence of exogenous ABA. Additionally, when 2-bp mutations were introduced into this promoter so that phytochrome responsiveness was lost, a response to exogenous ABA was still present. We conclude that phytochrome- and ABA-response elements are separable in the Lhcb2*1 promoter. We tested whether the effects of ABA on RNA abundance could be inhibited by treatment with gibberellin and found no evidence for such an inhibition. We have also found that the ABA-responsive Em promoter of wheat can be negatively regulated by phytochrome action. It is likely that this regulation is mediated at least in part by phytochrome-induced changes in ABA levels. Our results demonstrate that it is essential to take into account that dark treatments and the phytochrome system can affect ABA levels when interpreting studies of light-regulated genes.     

Phytochrome A and phytochrome B1 control the acquisition of competence for shoot regeneration in tomato hypocotyl

 We analysed the light-dependent acquisition of competence for adventitious shoot formation in hypocotyls of phytochrome A (fri) and phytochrome B1 (tri) mutants of tomato and their wild type by pre-growing the seedlings under different light quality. The regenerative response in vitro of explants from etiolated seedlings was reduced in comparison to that displayed by light-grown ones. Our results indicate that the light-dependent acquisition of competence for shoot regeneration in the tomato hypocotyl is regulated by phytochrome and antagonistically by a blue-light receptor. By using phytochrome mutants and narrow wave band light we showed that it is mediated at least by two distinct phytochrome species: phytochrome B1 and phytochrome A. The action of phytochrome B1 during seedling growth was sufficient to induce the full capacity of the subsequent regenerative response in vitro in explants from all positions along the hypocotyls. In contrast far-red light acting through phytochrome A did not induce the full capability of shoot regeneration from middle and basal segments of the hypocotyl when phytochrome B1 was absent (tri mutant). A few middle and basal hypocotyl explants pre-grown in blue light regenerated shoots. Received: 12 April 1999 / Revision received: 5 July 1999 · Accepted: 6 August 1999     

Nucleocytoplasmic partitioning of the plant photoreceptors phytochrome A,B, C,D, and E is regulated differentially by light and exhibits a diurnal rhythm

The phytochrome family of plant photoreceptors has a central role in the adaptation of plant development to changes in ambient light conditions. The individual phytochrome species regulate different or partly overlapping physiological responses. We generated transgenic Arabidopsis plants expressing phytochrome A to E:green fluorescent protein (GFP) fusion proteins to assess the biological role of intracellular compartmentation of these photoreceptors in light-regulated signaling. We show that all phytochrome:GFP fusion proteins were imported into the nuclei. Translocation of these photoreceptors into the nuclei was regulated differentially by light. Light-induced accumulation of phytochrome species in the nuclei resulted in the formation of speckles. The appearance of these nuclear structures exhibited distinctly different kinetics, wavelengths, and fluence dependence and was regulated by a diurnal rhythm. Furthermore, we demonstrate that the import of mutant phytochrome B:GFP and phytochrome A:GFP fusion proteins, shown to be defective in signaling in vivo, is regulated by light but is not accompanied by the formation of speckles. These results suggest that (1) the differential regulation of the translocation of phytochrome A to E into nuclei plays a role in the specification of functions, and (2) the appearance of speckles is a functional feature of phytochrome-regulated signaling.     

Phosphopeptide mapping of Avena phytochrome phosphorylated by protein kinases in vitro

We previously demonstrated that protein kinases are useful probes of conformational changes that occur upon photoconversion of phytochrome [Wong, Y.-S., Cheng, H.-C., Walsh, D. A., & Lagarias, J. C. (1986) J. Biol. Chem. 261, 12089-12097]. Here we present phosphopeptide analyses of oat phytochrome phosphorylated by three mammalian protein kinases and by a polycation-stimulated, phytochrome-associated protein kinase. Phosphorylation of the Pr form by the cAMP-dependent protein kinase occurs predominantly on Ser17 while Ser598 is the preferred phosphorylation site on Pfr. The cGMP-dependent and Ca2(+)-activated, phospholipid-dependent protein kinases, which phosphorylate only the Pr form of phytochrome, recognize the same region on the phytochrome polypeptide as the cAMP-dependent protein kinase. Polycation-stimulated phytochrome phosphorylation reveals that, in contrast to the mammalian enzymes, the plant kinase recognizes the serine-rich, blocked N-terminus of phytochrome. The potential regulatory role of phytochrome phosphorylation, particularly in the structurally conserved serine/threonine-rich N-terminal region of the phytochrome polypeptide, is suggested by these results.     

An amino-terminal deletion of rice phytochrome A results in a dominant negative suppression of tobacco phytochrome A activity in transgenic tobacco seedlings

Overexpression of phytochrome A results in an increased inhibition of hypocotyl elongation under red and far-red light. We used this approach to assay for the function of N-terminal mutations of rice (Oryza sativa L.) phytochrome A. Transgenic tobacco seedlings that express the wild-type rice phytochrome A (RW), a rice phytochrome A lacking the first 80 amino acids (NTD) or a rice phytochrome A with a conversion of the first 10 serines into alanine residues (S/A) were compared with untransformed wild-type tobacco (Nicotiana tabacum L. cv. Xanthi) seedlings. Experiments under different fluence rates showed that RW and, even more strongly, S/A increased the response under both red and far-red light, whereas NTD decreased the response under far-red light but hardly altered the response under red light. These results indicate that NTD not only lacks residues essential for an increased response under red light but also distorts the wild-type response under far-red light. Wild-type rice phytochrome A and, even more so, S/A mediate an enhanced phytochrome A as well as phytochrome B function, whereas NTD interferes with the function of endogenous tobacco phytochrome A as well as that of rice phytochrome A when co-expressed in a single host. Experiments with seedlings of different ages and various times of irradiation under far-red light demonstrated that the effect of NTD is dependent on the stage of development. Our results suggest that the lack of the first 80 amino acids still allows a rice phytochrome A to interact with the phytochrome transduction pathway, albeit nonproductively in tobacco seedlings.Abbreviations HIR high-irradiance response - NTD N-terminal deletion mutant of rice phytochrome A - Pfr far-red-absorbing form of phytochrome - Pr red-absorbing form of phytochrome - RW rice wild-type phytochrome A - S/A serine-to-alanine mu-tant of rice phytochrome A - wNTD weakly expressing NTD line - XAN wild-type tobacco cv. Xanthi We thank Masaki Furuya (Adv. Research Laboratory, Hitachi, Saitama, Japan) and Akira Nagatani (RIKEN Institute, Saitama, Japan) for providing the monoclonal antibodies mAP5 and mAR14. The work was supported by a grant from the Human Frontier Science Program. K.E. was a recipient of a Landesgraduiertenförderung fellowship.     

Phytochrome A regulates red-light induction of phototropic enhancement in Arabidopsis.

Phytochrome A (phyA) and phytochrome B photoreceptors have distinct roles in the regulation of plant growth and development. Studies using specific photomorphogenic mutants and transgenic plants overexpressing phytochrome have supported an evolving picture in which phyA and phytochrome B are responsive to continuous far-red and red light, respectively. Photomorphogenic mutants of Arabidopsis thaliana that had been selected for their inability to respond to continuous irradiance conditions were tested for their ability to carry out red-light-induced enhancement of phototropism, which is an inductive phytochrome response. We conclude that phyA is the primary photoreceptor regulating this response and provide evidence suggesting that a common regulatory domain in the phyA polypeptide functions for both high-irradiance and inductive phytochrome responses.     

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.     

High pigment1 mutation negatively regulates phototropic signal transduction in tomato seedlings

Phototropins and phytochromes are the major photosensory receptors in plants and they regulate distinct photomorphogenic responses. The molecular mechanisms underlying functional interactions of phototropins and phytochromes remain largely unclear. We show that the tomato (Lycopersicon esculentum) phytochrome A deficient mutant fri lacks phototropic curvature to low fluence blue light, indicating requirement for phytochrome A for expression of phototropic response. The hp1 mutant that exhibits hypersensitive responses to blue light and red light reverses the impairment of second-positive phototropic response in tomato in phytochrome A-deficient background. Physiological analyses indicate that HP1 functions as a negative regulator of phototropic signal transduction pathway, which is removed via action of phytochrome A. The loss of HP1 gene product in frihp1 double mutant allows the unhindered operation of phototropic signal transduction chain, obviating the need for the phytochrome action. Our results also indicate that the role of phytochrome in regulating phototropism is restricted to low fluence blue light only, and at high fluence blue light, the phytochrome A-deficient fri mutant shows the normal phototropic response.     

Sustained but not transient phytochrome A signaling targets a region of an Lhcb1*2 promoter not necessary for phytochrome B action

Current evidence is inconclusive regarding the point of signaling convergence downstream from different members of the phytochrome family. In transgenic Arabidopsis, the activity of a reporter enzyme under the control of the -453 to +67 fragment of an Lhcb1*2 promoter shows very low fluence responses (VLFRs) and high-irradiance responses (HIRs) mediated by phytochrome A and low-fluence responses (LFRs) mediated by phytochrome B. A 5' deletion of the promoter to -134 abolished the HIR without affecting VLFR or LFR. In transgenic tobacco, VLFR and LFR were observed for the -176 to -31 or -134 to -31 fragments of Lhcb1*2 fused to 35S cauliflower mosaic virus minimal promoters, but only the largest fragment showed HIR. We propose that sustained activation of phytochrome A with far-red light initiates a signaling cascade that deviates from phytochrome B signaling and transient phytochrome A signaling and that this divergence extends as far as the Lhcb1*2 promoter.     

Overexpression of rice phytochrome A partially complements phytochrome B deficiency in Arabidopsis

The red/far-red reversible phytochromes play a central role in regulating the development of plants in relation to their light environment. Studies on the roles of different members of the phytochrome family have mainly focused on light-labile, phytochrome A and light-stable, phytochrome B. Although these two phytochromes often regulate identical responses, they appear to have discrete photosensory functions. Thus, phytochrome A predominantly mediates responses to prolonged far-red light, as well as acting in a non-red/far-red-reversible manner in controlling responses to light pulses. In contrast, phytochrome B mediates responses to prolonged red light and acts photoreversibly under light-pulse conditions. However, it has been reported that rice (Oryza sativa L.) phytochrome A operates in a classical red/far-red reversible fashion following its expression in transgenic tobacco plants. Thus, it was of interest to determine whether transgenic rice phytochrome A could substitute for loss of phytochrome B in phyB mutants of Arabidopsis thaliana (L.) Heynh. We have observed that ectopic expression of rice phytochrome A can correct the reduced sensitivity of phyB hypocotyls to red light and restore their response to end-of-day far-red treatments. The latter is widely regarded as a hallmark of phytochrome B action. However, although transgenic rice phytochrome A can correct other aspects of elongation growth in the phyB mutant it does not restore other responses to end-of-day far-red treatments nor does it restore responses to low red:far-red ratio. Furthermore, transgenic rice phytochrome A does not correct the early-flowering phenotype of phyB seedlings. Received: 12 July 1998 / Accepted: 13 August 1998     

The 5''-proximal region of the wheat Cab-1 gene contains a 268-bp enhancer-like sequence for phytochrome response.

We have previously reported that the expression of the wheat Cab-1 gene is subject to phytochrome regulation and a 1.8-kb 5' upstream sequence of this gene is sufficient for the regulated expression. To delineate sequences for the phytochrome response we analyzed a series of 5' deletion mutants as well as chimeric gene constructs comprising different sequences of the Cab-1 upstream region in transgenic tobacco seedlings. We found that a deletion mutant containing a 357-bp 5' upstream sequence still exhibits maximal levels of phytochrome-regulated expression. A 268-bp enhancer-like element, located between -89 and -357, is responsible for the phytochrome response of the Cab-1 gene; sequences upstream from -357 to -843 and downstream from -124 to +1100 are probably not involved. Finally, we show that the Cab-1 mRNA stability is not regulated by phytochrome.     

Phytochrome phosphorylation modulates light signaling by influencing the protein-protein interaction

Plant photoreceptor phytochromes are phosphoproteins, but the question as to the functional role of phytochrome phosphorylation has remained to be elucidated. We investigated the functional role of phytochrome phosphorylation in plant light signaling using a Pfr-specific phosphorylation site mutant, Ser598Ala of oat (Avena sativa) phytochrome A (phyA). The transgenic Arabidopsis thaliana (phyA-201 background) plants with this mutant phyA showed hypersensitivity to light, suggesting that phytochrome phosphorylation at Serine-598 (Ser598) in the hinge region is involved in an inhibitory mechanism. The phosphorylation at Ser598 prevented its interaction with putative signal transducers, Nucleoside Diphosphate Kinase-2 and Phytochrome-Interacting Factor-3. These results suggest that phosphorylation in the hinge region of phytochromes serves as a signal-modulating site through the protein-protein interaction between phytochrome and its putative signal transducer proteins.