Signaling activities among the Arabidopsis phyB/D/E-type phytochromes: a major role for the central region of the apoprotein

The Arabidopsis phyB, phyD, and phyE phytochromes regulate plant developmental and growth responses to continuous red light (R) and to the ratio of R to far-red (FR) light. The activities of these three photoreceptors in the control of seedling growth have been compared using a transgenic assay based upon induction of R-hypersensitivity of hypocotyl elongation by overexpression of the apoproteins from the 35S promoter. 35S-phyB, 35S-phyD, and 35S-phyE lines expressing similar levels of the respective phytochromes were isolated. Under pulses of R, phyB is very active in inducing a dwarf hypocotyl phenotype, whereas phyD and phyE are inactive. Under high-fluence continuous R, phyD shows a gain in activity whereas phyE does not. These results demonstrate significant differences in the inherent regulatory activities of these receptor apoproteins. To localize the sequence determinants of these functional differences, chimeric proteins were constructed by shuffling amino-terminal, central, and carboxy-terminal regions of phyB and phyD. Overexpression analysis of the phyB/D chimeras shows that it is the central region of these proteins that is most critical in determining their respective activities.     

Genetic and transgenic evidence that phytochromes A and B act to modulate the gravitropic orientation of Arabidopsis thaliana hypocotyls

Hypocotyls of Arabidopsis thaliana exhibit negative gravitropism in the dark, growing against the gravity vector. The direction of growth is randomized in red light (R). In single mutants lacking either phytochrome A or B randomization of hypocotyl orientation in R is retained. However, a double mutant lacks this response, indicating that either phytochrome A or B is capable of inducing randomization and phytochrome A and B are the only phytochromes involved in this process. The induction of randomization was confirmed using lines that express to different levels PHYA and PHYB cDNAs. Overexpression of PHYA cDNAs induced randomization of hypocotyl orientation in the dark. Dark randomization was also seen in the phyB-1 mutant but not in two other phyB alleles, suggesting that dark randomization in the phyB-1 line may be due to a second mutation. When germination was induced by gibberellin, rather than exposure to brief white light, randomization in the dark associated with phytochrome A overproduction was not observed but was retained in the phyB-1 mutant. Overexpression of PHYB cDNAs induced a light-dependent randomization of hypocotyl orientation that responded to R:far-red light ratio. We conclude that the default situation in Arabidopsis hypocotyls is, therefore, negative gravitropism, and either phytochrome A or phytochrome B can mediate randomization.     

Overexpression of homologous phytochrome genes in tomato: exploring the limits in photoperception

Transgenic tomato [Lycopersicon esculentum (=Solanum lycopersicum)] lines overexpressing tomato PHYA, PHYB1, or PHYB2, under control of the constitutive double-35S promoter from cauliflower mosaic virus (CaMV) have been generated to test the level of saturation in individual phytochrome-signalling pathways in tomato. Western blot analysis confirmed the elevated phytochrome protein levels in dark-grown seedlings of the respective PHY overexpressing (PHYOE) lines. Exposure to 4 h of red light resulted in a decrease in phytochrome A protein level in the PHYAOE lines, indicating that the chromophore availability is not limiting for assembly into holoprotein and that the excess of phytochrome A protein is also targeted for light-regulated destruction. The elongation and anthocyanin accumulation responses of plants grown under white light, red light, far-red light, and end-of-day far-red light were used for characterization of selected PHYOE lines. In addition, the anthocyanin accumulation response to different fluence rates of red light of 4-d-old dark-grown seedlings was studied. The elevated levels of phyA in the PHYAOE lines had little effect on seedling and adult plant phenotype. Both PHYAOE in the phyA mutant background and PHYB2OE in the double-mutant background rescued the mutant phenotype, proving that expression of the transgene results in biologically active phytochrome. The PHYB1OE lines showed mild effects on the inhibition of stem elongation and anthocyanin accumulation and little or no effect on the red light high irradiance response. By contrast, the PHYB2OE lines showed a strong inhibition of elongation, enhancement of anthocyanin accumulation, and a strong amplification of the red light high irradiance response.     

Differential patterns of expression of the Arabidopsis PHYB, PHYD, and PHYE phytochrome genes.

The Arabidopsis thaliana phyB, phyD, and phyE phytochrome apoproteins show higher amino acid sequence similarity to each other than to phyA or phyC, they are the most recently evolved members of this photoreceptor family, and they may interact in regulating photomorphogenesis. The expression patterns of translational fusions of the 5' upstream regions of the PHYB, PHYD, and PHYE genes to the beta-glucuronidase (GUS) coding sequence were compared. PD-GUS and PE-GUS fusions were 5- to 10-fold less active than a PB-GUS fusion, but all three promoter regions drove expression of the reporter gene in all stages of the plant's life cycle. Over the first 10 d of seedling growth, the PHYB and PHYD promoters were more active in the dark than in the light, whereas the opposite was true of the PHYE promoter. Unlike the PB-GUS construct, which was expressed in most parts of seedlings and mature plants, the PD-GUS and PE-GUS transgenes showed differential expression, notably in leaves, flower organs, and root tips. Tissue sections showed that the three promoters are coexpressed in at least some leaf cells. Hence, the PHYB, PHYD, and PHYE genes differ in expression pattern but these patterns overlap and interaction of these receptor forms within individual cells is possible.     

Suppressors of an Arabidopsis thaliana phyB mutation identify genes that control light signaling and hypocotyl elongation.

Ambient light controls the development and physiology of plants. The Arabidopsis thaliana photoreceptor phytochrome B (PHYB) regulates developmental light responses at both seedling and adult stages. To identify genes that mediate control of development by light, we screened for suppressors of the long hypocotyl phenotype caused by a phyB mutation. Genetic analyses show that the shy (short hypocotyl) mutations we have isolated fall in several loci. Phenotypes of the mutants suggest that some of the genes identified have functions in control of light responses. Other loci specifically affect cell elongation or expansion.     

Identification of phytochrome B amino acid residues mutated in three new phyB mutants of Arabidopsis thaliana

The growth and development of plants is regulated by light viathe action of photoreceptors which are responsive to the red/far-red,blue and UV regions of the spectrum. Phytochrome B (the apoproteinof which is encoded by the PHYB gene) is one of the red/far-redabsorbing photoreceptors active in this process. In this paper,the isolation and characterization of three new EMS-inducedmutations of Arabidopsis which confer phytochrome B deficiencyare described. Complementation analysis showed that these mutations(phyB-101, phyB-102 and phyB-104) were allelic with PHYB. DNAsequence analysis showed that all three mutants contain nucleotidesubstitutions in the PHYB-101 gene sequence. phyB-101 carriesa nucleotide substitution within the second exon of the PHYBgene. This G-to-A substitution is a missense mutation that convertsa glutamate residue at position 812 of the phytochrome B apoproteinto a lysine residue. phyB-102, another missense mutant, carriesa C-to-T substitution which converts a serine residue at position349 of the phytochrome B apoprotein to a phenylalanine residue.phyB-104 carries a premature stop codon as a result of a G-to-Amutation 1190 bp down-stream of the ATG start codon of the PHYBsequence. The missense mutations in phyB-101 and phyB-102 causesignificant alterations in the predicted second ary structureof their respective mutant polypeptides, and identify aminoacid residues playing crucial roles in phytochrome B function,assembly or stability. Key words: Arabidopsis thaliana, phytochromet, phyB mutants, missense mutations     

Altered dark- and photoconversion of phytochrome B mediate extreme light sensitivity and loss of photoreversibility of the phyB-401 mutant

The phyB-401 mutant is 10(3) fold more sensitive to red light than its wild-type analogue and shows loss of photoreversibility of hypocotyl growth inhibition. The phyB-401 photoreceptor displays normal spectral properties and shows almost no dark reversion when expressed in yeast cells. To gain insight into the molecular mechanism underlying this complex phenotype, we generated transgenic lines expressing the mutant and wild-type phyB in phyB-9 background. Analysis of these transgenic lines demonstrated that the mutant photoreceptor displays a reduced rate of dark-reversion but normal P(fr) to P(r) photoconversion in vivo and shows an altered pattern of association/dissociation with nuclear bodies compared to wild-type phyB. In addition we show (i) an enhanced responsiveness to far-red light for hypocotyl growth inhibition and CAB2 expression and (ii) that far-red light mediated photoreversibility of red light induced responses, including inhibition of hypocotyl growth, formation of nuclear bodies and induction of CAB2 expression is reduced in these transgenic lines. We hypothesize that the incomplete photoreversibility of signalling is due to the fact that far-red light induced photoconversion of the chromophore is at least partially uncoupled from the P(fr) to P(r) conformation change of the protein. It follows that the phyB-401 photoreceptor retains a P(fr)-like structure (P(r) (*)) for a few hours after the far-red light treatment. The greatly reduced rate of dark reversion and the formation of a biologically active P(r) (*) conformer satisfactorily explain the complex phenotype of the phyB-401 mutant and suggest that amino acid residues surrounding the position 564 G play an important role in fine-tuning phyB signalling.     

Independent action of ELF3 and phyB to control hypocotyl elongation and flowering time

Light regulates various aspects of plant growth, and the photoreceptor phytochrome B (phyB) mediates many responses to red light. In a screen for Arabidopsis mutants with phenotypes similar to those of phyB mutants, we isolated two new elf3 mutants. One has weaker morphological phenotypes than previously identified elf3 alleles, but still abolishes circadian rhythms under continuous light. Like phyB mutants, elf3 mutants have elongated hypocotyls and petioles, flower early, and have defects in the red light response. However, we found that elf3 mutations have an additive interaction with a phyB null mutation, with phyA or hy4 null mutations, or with a PHYB overexpression construct, and that an elf3 mutation does not prevent nuclear localization of phyB. These results suggest that either there is substantial redundancy in phyB and elf3 function, or the two genes regulate distinct signaling pathways.     

Phytochrome A and Phytochrome B Have Overlapping but Distinct Functions in Arabidopsis Development

Plant responses to red and far-red light are mediated by a family of photoreceptors called phytochromes. In Arabidopsis thaliana, there are genes encoding at least five phytochromes, and it is of interest to learn if the different phytochromes have overlapping or distinct functions. To address this question for two of the phytochromes in Arabidopsis, we have compared light responses of the wild type with those of a phyA null mutant, a phyB null mutant, and a phyA phyB double mutant. We have found that both phyA and phyB mutants have a deficiency in germination, the phyA mutant in far-red light and the phyB mutant in the dark. Furthermore, the germination defect caused by the phyA mutation in far- red light could be suppressed by a phyB mutation, suggesting that phytochrome B (PHYB) can have an inhibitory as well as a stimulatory effect on germination. In red light, the phyA phyB double mutant, but neither single mutant, had poorly developed cotyledons, as well as reduced red-light induction of CAB gene expression and potentiation of chlorophyll induction. The phyA mutant was deficient in sensing a flowering response inductive photoperiod, suggesting that PHYA participates in sensing daylength. In contrast, the phyB mutant flowered earlier than the wild type (and the phyA mutant) under all photoperiods tested, but responded to an inductive photoperiod. Thus, PHYA and PHYB appear to have complementary functions in controlling germination, seedling development, and flowering. We discuss the implications of these results for possible mechanisms of PHYA and PHYB signal transduction.     

Forward genetic analysis of the circadian clock separates the multiple functions of ZEITLUPE

The circadian system of Arabidopsis (Arabidopsis thaliana) includes feedback loops of gene regulation that generate 24-h oscillations. Components of these loops remain to be identified; none of the known components is completely understood, including ZEITLUPE (ZTL), a gene implicated in regulated protein degradation. ztl mutations affect both circadian and developmental responses to red light, possibly through ZTL interaction with PHYTOCHROME B (PHYB). We conducted a large-scale genetic screen that identified additional clock-affecting loci. Other mutants recovered include 11 new ztl alleles encompassing mutations in each of the ZTL protein domains. Each mutation lengthened the circadian period, even in dark-grown seedlings entrained to temperature cycles. A mutation of the LIGHT, OXYGEN, VOLTAGE (LOV)/Period-ARNT-Sim (PAS) domain was unique in retaining wild-type responses to red light both for the circadian period and for control of hypocotyl elongation. This uncoupling of ztl phenotypes indicates that interactions of ZTL protein with multiple factors must be disrupted to generate the full ztl mutant phenotype. Protein interaction assays showed that the ztl mutant phenotypes were not fully explained by impaired interactions with previously described partner proteins Arabidopsis S-phase kinase-related protein 1, TIMING OF CAB EXPRESSION 1, and PHYB. Interaction with PHYB was unaffected by mutation of any ZTL domain. Mutation of the kelch repeat domain affected protein binding at both the LOV/PAS and the F-box domains, indicating that interaction among ZTL domains leads to the strong phenotypes of kelch mutations. Forward genetics continues to provide insight regarding both known and newly discovered components of the circadian system, although current approaches have saturated mutations at some loci.     

shl, a New set of Arabidopsis mutants with exaggerated developmental responses to available red, far-red, and blue light

The interaction of light perception with development is the subject of intensive genetic analysis in the model plant Arabidopsis. We performed genetic screens in low white light-a threshold condition in which photomorphogenetic signaling pathways are only partially active-for ethyl methane sulfonate-generated mutants with altered developmental phenotypes. Recessive mutants with exaggerated developmental responses were obtained in eight complementation groups designated shl for seedlings hyperresponsive to light. shl1, shl2, shl5, and shl3 shl4 (double mutant) seedlings showed limited or no phenotypic effects in darkness, but showed significantly enhanced inhibition of hypocotyl elongation in low-white, red, far-red, blue, and green light across a range of fluences. These results reflect developmental hyper-responsiveness to signals generated by both phytochrome and cryptochrome photoreceptors. The shl11 mutant retained significant phenotypic effects on hypocotyl length in both the phyA mutant and phyB mutant backgrounds but may be dependent on CRY1 for phenotypic expression in blue light. The shl2 phenotype was partially dependent on PHYB, PHYA, and CRY1 in red, far-red, and blue light, respectively. shl2 and, in particular, shl1 were partially dependent on HY5 activity for their light-hyperresponsive phenotypes. The SHL genes act (genetically) as light-dependent negative regulators of photomorphogenesis, possibly in a downstream signaling or developmental pathway that is shared by CRY1, PHYA, and PHYB and other photoreceptors (CRY2, PHYC, PHYD, and PHYE).     

The involvement of gibberellin 20-oxidase genes in phytochrome-regulated petiole elongation of Arabidopsis

Long day (LD) exposure of rosette plants causes rapid stem/petiole elongation, a more vertical growth habit, and flowering; all changes are suggestive of a role for the gibberellin (GA) plant growth regulators. For Arabidopsis (Arabidopsis thaliana) L. (Heynh), we show that enhancement of petiole elongation by a far-red (FR)-rich LD is mimicked by a brief (10 min) end-of-day (EOD) FR exposure in short day (SD). The EOD response shows red (R)/FR photoreversibility and is not affected in a phytochrome (PHY) A mutant so it is mediated by PHYB and related PHYs. FR photoconversion of PHYB to an inactive form activates a signaling pathway, leading to increased GA biosynthesis. Of 10 GA biosynthetic genes, expression of the 20-oxidase, AtGA20ox2, responded most to FR (up to a 40-fold increase within 3 h). AtGA20ox1 also responded but to a lesser extent. Stimulation of petiole elongation by EOD FR is reduced in a transgenic AtGA20ox2 hairpin gene silencing line. By contrast, it was only in SD that a T-DNA insertional mutant of AtGA20ox1 (ga5-3) showed reduced response. Circadian entrainment to a daytime pattern provides an explanation for the SD expression of AtGA20ox1. Conversely, the strong EOD/LD FR responses of AtGA20ox2 may reflect its independence of circadian regulation. While FR acting via PHYB increases expression of AtGA20ox2, other GA biosynthetic genes are known to respond to R rather than FR light and/or to other PHYs. Thus, there must be different signal transduction pathways, one at least showing a positive response to active PHYB and another showing a negative response.     

Increased phytochrome B alleviates density effects on tuber yield of field potato crops

The possibility that reduced photomorphogenic responses could increase field crop yield has been suggested often, but experimental support is still lacking. Here, we report that ectopic expression of the Arabidopsis PHYB (phytochrome B) gene, a photoreceptor involved in detecting red to far-red light ratio associated with plant density, can increase tuber yield in field-grown transgenic potato (Solanum tuberosum) crops. Surprisingly, this effect was larger at very high densities, despite the intense reduction in the red to far-red light ratios and the concomitant narrowed differences in active phytochrome B levels between wild type and transgenics at these densities. Increased PHYB expression not only altered the ability of plants to respond to light signals, but they also modified the light environment itself. This combination resulted in larger effects of enhanced PHYB expression on tuber number and crop photosynthesis at high planting densities. The PHYB transgenics showed higher maximum photosynthesis in leaves of all strata of the canopy, and this effect was largely due to increased leaf stomatal conductance. We propose that enhanced PHYB expression could be used in breeding programs to shift optimum planting densities to higher levels.     

Transgenic complementation of the hy3 phytochrome B mutation and response to PHYB gene copy number in Arabidopsis

A recombinant PHYB minigene (m PHYB ) consisting of the complete Arabidopsis PHYB cDNA sequence fused to 2.3 kb of upstream PHYB promoter sequence has been introduced into wild-type Arabidopsis and into a strain containing the Bo64 allele of the hy3 mutation. The Bo64 mutant has previously been shown to contain a nonsense mutation in the PHYB coding sequence. Transformation of this strain with the m PHYB gene results in complementation of all of the mutant phenotypic characteristics tested including hypocotyl length and hypocotyl cell size, response to end-of-day far-red light, leaf morphology, chlorophyll level, and flowering time. Presence of the m PHYB transgene in a wild-type genetic background causes exaggeration of this same set of phenotypic characteristics, indicating that these diverse photomorphogenic responses are sensitive to the copy number of the PHYB gene. The transgene inserts in the Bo64(m PHYB ) and WT(m PHYB ) lines are shown to be single locus and single copy and the immunologically detectable level of phytochrome B is shown to vary linearly with PHYB gene copy number. These results demonstrate a complex role for phytochrome B in Arabidopsis photomorphogenesis and suggest that the expression level of this phytochrome gene is an important determinant of the intensity of light-induced plant responses.     

HYPERSENSITIVE TO RED AND BLUE 1 and its C-terminal regulatory function control FLOWERING LOCUS T expression

The red and far-red light-absorbing phytochromes and UV-A/blue light-absorbing cryptochromes regulate seedling de-etiolation and flowering responses. The signaling steps that mediate the photoreceptor regulation on key flowering genes remain largely unknown. We report that a previously identified photomorphogenic mutant, hypersensitive to red and blue 1 (hrb1), flowered late and showed attenuated expression of FLOWERING LOCUS T (FT) over both long days and short days. Transgenic plants that overexpress the full-length HRB1, or its C-terminal half, flowered early and accumulated more FT messages under short-day conditions. The transgenic plants also displayed hyposensitive de-etiolation phenotypes, and the expression of these phenotypes requires the action of PIF4. The double mutant of hrb1/cry2 showed a flowering phenotype and an FT expression pattern similar to hrb1 under long-day conditions, suggesting that HRB1 may function downstream of cry2 under long-day conditions. In contrast, hrb1/phyB-9 showed a flowering phenotype and an FT expression pattern similar to phyB-9 over both long days and short days, indicating a modulatory role of HRB1 in the flowering pathway mediated by phyB. Overexpression of HRB1 did not affect the expression of the central clock oscillators, TOC1 and CCA1. HRB1 therefore represents a signaling step that regulates FT expression downstream of red and blue light perception.     

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.     

Suppressor of <Emphasis Type="Italic">bri1-120</Emphasis> mutant allele revealed interrelated and independent actions of brassinosteroid and light signaling

Brassinosteroids (BRs) are plant hormones that affect diverse aspects of plant development. Various BR-biosynthetic or BR-signaling mutants contribute to BR functions and signaling events in many plant species. The BR receptor brassinosteroid-Insensitive 1 (BRI1) plays critical roles in BR signaling. We previously identified a weak bri1 mutant allele, bri1-120, that has a mutation site in the extracellular domain of BRI1. Here, genetic suppressor screening revealed that a PHYB gene mutation led to suppression of ethyl methanesulfonate (EMS)-mutagenized bri1-120. The morphology of bri1-120phyB-1 indicated that compact and rounded phenotypes of bri1-120 were suppressed. However, BR sensitivity of the bri1-120phyB-1 was only recovered in hypocotyl elongation, and overexpression of PHYB in bri1-120 did not enhance bri1-120 phenotypes. To further investigate the relationship between BR and light signalings, we examined the seed germination pattern and hypocotyl growth of bri1-120phyB-1 as compared to that of each single mutant under various light conditions. Seed germination in bri1-120phyB-1 was higher than in both the single mutants. Hypocotyl length in bri1-120phyB-1 was intermediate between that of bri1-120 and phyB-1, whereas sensitivity to red light in bri1-120phyB-1 remained the same as in phyB-1. These results suggest that BR and light signalings affect diverse cellular responses both together and independently, depending on the specific cellular processes.