Identification of photo-inactive phytochrome A in etiolated seedlings and photo-active phytochrome B in green leaves of the aurea mutant of tomato

The contents of spectrophotometrically measurable phytochrome A (PhyA) and phytochrome B (PhyB) and the corresponding immunochemically detectable apoproteins (PHYA and PHYB) were examined in dark- and light-grown tissues of the aurea mutant of tomato and its wild-type (WT). The amount of PHYA in etiolated aurea seedlings was found to be about 20% of that in the WT; this PHYA showed no photoreversible changes in absorbance, no downregulation of the level of PHYA in light-grown seedlings, and no differential proteolysis of Pr and Pfr species in vitro which was seen in the case of the WT. By contrast, the amount of PHYB in aurea seedlings was not significantly different from that in WT seedlings. Phytochrome isolated from green leaves of the aurea mutant and purified by ion-exchange chromatography showed a red/far-red reversible spectral change, and its elution profile during chromatography was essentially similar to that of PHYB. The results indicate that aurea is a mutant that is deficient in photoactive PhyA at the etiolated stage, when it contains a spectrally inactive PHYA. However, the mutant contains spectrally active PhyB in its green tissue as does the WT.     

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.     

Photoresponses of Light-Grown phyA Mutants of Arabidopsis (Phytochrome A Is Required for the Perception of Daylength Extensions)

Several aspects of the photophysiology of wild-type Arabidopsis thaliana seedlings were compared with those of a phytochrome A null mutant, phyA-1, and a mutant, fhy1, that is putatively involved in the transduction of light signals from phytochrome A. Although phyA seedlings display a near wild-type phenotype when grown in white light (W), they nevertheless display several photomorphogenic abnormalities. Thus, whereas the germination of wild-type and fhy1 seeds is almost fully promoted by a pulse of red light (R) or by continuous far-red light (FR), phyA seed germination is responsive only to R. Following growth under day/night cycles, but not under continuous W, the hypocotyls of light-grown phyA and fhy1 seedlings are more elongated than those of wild-type seedlings. For seedlings grown under low red/far-red (R/FR) ratio light conditions, phyA and fhy1 seedlings display a more marked promotion of hypocotyl elongation than wild-type seedlings. Similarly, seedlings that are doubly null for phytochrome A and phytochrome B(phyA phyB) also have more elongated hypocotyls under low R/FR ratio conditions than phyB seedlings. This indicates that phytochrome A action in light-grown seedlings is antagonistic to the action of phytochrome B. Although wild-type, fhy1, and phyA seedlings flower at essentially the same time under both short-day and long-day conditions, an obvious consequence of phytochrome A deficiency is a pronounced late flowering under conditions where a short day of 8 h of fluorescent W is extended by 8 h of low-fluence-rate incandescent light. The evidence thus indicates that phytochrome A plays a role in seed germination, in the control of elongation growth of light-grown seedlings, and in the perception of daylength.     

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.     

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.     

Analysis of phytochrome-deficient yellow-green-2 and aurea mutants of tomato

Two alleles of the yellow-green-2 ( yg-2) and eight different alleles of the aurea ( au ) locus of tomato ( Lycopersicon esculentum Mill.) were compared. All are characterized by a paler green colour compared with wild-type (WT), an elongated hypocotyl in red light, and low or below detection limits of spectrophotometrically active phytochrome. Hypocotyl length was variable in white light, ranging from that of WT to more elongated. Immunochemical analysis revealed that etiolated seedlings of the yg-2 mutant have approximately 25% of the WT level of phytochrome A protein (PHYA), whereas that of phytochrome B protein (PHYB) is normal. In this it resembles the au mutant. The au,yg-2 double mutant has a more extreme chlorophyll deficiency than either parent. Since the yg-2 and au mutants have a less severe phenotype at the adult stage, that is, are leaky, the additive effect can be explained by assuming that the mutants control two steps in the chromophore biosynthesis pathway. Combination, by crossing, of the yg-2 and au mutants with a transgenic tomato line that overexpresses oat phytochrome A3 (PhyA-3) essentially failed to restore the WT phenotype under white fluorescent light conditions, although under greenhouse conditions some evidence for increased sensitivity to light was observed. Immunochemically, oat PHYA-3 protein is detectable in both the yg-2,PhyA-3 and au,PhyA-3 'double' mutants. Spectrophotometrical analysis, however, revealed that holophytochrome was undetectable in the yg-2,PhyA-3 and au,PhyA-3 'double' mutants. These results are compatible with both mutants being disturbed in phytochrome chromophore biosynthesis.     

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.     

Stem extension-growth responses to blue light require Pfr in tomato seedlings but are not reduced by the low phytochrome levels of the aurea mutant

The effects of blue light (B) on stem extension growth were investigated in wild-type (WT) and aurea (au ) mutant seedlings of tomato. The au mutant has reduced phytochrome levels. Etiolated seedlings were grown under background red light (R) or far-red light (FR) with or without B. Hypocotyl growth was inhibited by B added to R but not by B added to FR, both in WT and au seedlings. The levels of B and/or R reaching the stem of fully de-etiolated seedlings grown in a glasshouse were reduced by means of collars around it. Both in WT and au -mutant seedlings the responses to B were larger at high than at low R/FR quantum ratios. In etiolated and light-grown au seedlings, changing the levels of phytochrome-absorbable radiation did not cause the same effect as changing B levels, indicating the action of specific BL/UV-A photoreceptor(s) (BAP). The responses to B are reduced by the low calculated levels of Pfr established by light treatments but not by the low levels of phytochrome present in the au mutant. The au mutant appears to be deficient in a phytochrome pool that is not essential for the interdependent co-action observed between phytochrome and BAP in the control of stem extension growth in tomato.     

Selected Components of the Shade-Avoidance Syndrome Are Displayed in a Normal Manner in Mutants of Arabidopsis thaliana and Brassica rapa Deficient in Phytochrome B

Several growth parameters associated with the phytochrome-mediated shade avoidance syndrome have been measured in seedlings and mature plants of a wild-type and a hy3 mutant of Arabidopsis thaliana deficient in phytochrome B. Growth parameters were compared in plants grown in either white light (high red:far-red [R:FR] ratio) or white light plus added far-red (FR) light (low R:FR ratio). Wild-type Arabidopsis exhibited increased hypocotyl and petiole extension under a low, compared with a high, R:FR ratio. The hy3 mutant did not respond to low R:FR ratio by increase in hypocotyl or petiole length. Extension growth of wild-type plants was stimulated by brief end-of-day FR pulses, but similar treatment had no effect on extension growth of hy3 mutant plants. However, some responses to low R:FR ratio seen in the wild-type plants were also evident in the hy3 mutants. The number of days to bolting, the developmental stage at bolting, the leaf area, and the specific stem weight (weight per unit of length) all decreased in the wild-type and hy3 seedlings in response to low R:FR ratio. Low R:FR ratio caused a larger decrease in leaf area and specific stem weight in the mutant seedlings than in wild-type seedlings. The effects of low R:FR ratio on leaf area and specific stem weight were opposite to those of the hy3 lesion, which resulted in increased leaf area and specific stem weight in comparison with the wild type. Both leaf area and specific stem weight responses to low R:FR ratio also were unchanged in the ein mutant of Brassica rapa, known to be deficient in phytochrome B. These responses represent components of the shade-avoidance syndrome, and, consequently, the results indicate that phytochrome B cannot be solely responsible for the perception of R:FR ratio and the induction of shade-avoidance responses. The hypothesis is proposed that different phytochromes may be responsible for the regulation of extension growth and the regulation of lateral or radial expansion.     

The cucumber long hypocotyl mutant lacks a light-stable PHYB-like phytochrome.

A novel cDNA sequence homologous to a phytochrome B (phyB) gene that was isolated in a library from tobacco tissue has been used in an Escherichia coli expression system to raise anti-phytochrome B (anti-PHYB) polypeptide-specific monoclonal antibodies. The specificity of these antibodies has been tested by cross-reactivity against purified pea light-labile type 1 and light-stable type 2 phytochromes, with some antibodies reacting with the type 2 and none with the type 1 phytochromes. One such antibody, monoclonal mAT1, has been employed to analyze the phytochrome molecular species present in a photomorphogenic long hypocotyl (lh) mutant of cucumber. The results indicated that the mutant contains wild-type levels of the light-labile type 1 phytochrome polypeptide (PHYA), which has an apparent molecular mass of approximately 120 kD, but shows less than 1% (detection limit) of a light-stable polypeptide recognized by mAT1 in wild-type seedlings. This protein, not detectable in the lh mutant, has the properties of light-stable type 2 phytochrome, has an apparent molecular mass of 116 to 117 kD, and remains at constant levels under continuous low-fluence-rate red light. Therefore, we conclude that the lh mutant lacks at least one type 2 phytochrome-like polypeptide, most probably a phyB gene product. The correlation between the lack of this protein and the deficiency or absence of physiological responses to a light-stable phytochrome species in this mutant helps to identify the physiological roles played by the products of different subfamilies within the phytochrome gene family.     

Rice phytochrome A controls apical hook opening after a single light pulse in transgenic tobacco seedlings

Apical hook opening in tobacco seedlings can be induced by a single red light pulse and this induction can be reverted by a subsequent far-red light pulse. The slow hook opening kinetics and the reversibility of an inductive light pulse even after 8 h of darkness indicate the involvement of stable phytochrome. Compared with wild-type, transgenic BN1 seedlings which overexpress rice phytochrome A exhibit a higher sensitivity to low irradiance red light pulses. Moreover, in BN1 seedlings an inductive red light pulse is only partially reversible even after 30 min, whereas wild-type tobacco seedlings show complete reversibility during the entire hook opening process. The data found show that rice phytochrome A is active in transgenic tobacco seedlings in controlling hook opening and that the introduced rice phytochrome A and the endogenous stable phytochrome behave differently in this response.     

Expression of functional oat phytochrome A in transgenic rice.

To investigate the biological functions of phytochromes in monocots, we generated, by electric discharge particle bombardment, transgenic rice (Oryza sativa cv Gulfmont) that constitutively expresses the oat phytochrome A apoprotein. The introduced 124-kD polypeptide bound chromophore and assembled into a red- and far-red-light-photoreversible chromoprotein with absorbance spectra indistinguishable from those of phytochrome purified from etiolated oats. Transgenic lines expressed up to 3 and 4 times more spectrophotometrically detectable phytochrome than wild-type plants in etiolated and green seedlings, respectively. Upon photo-conversion to the far-red-absorbing form of phytochrome, oat phytochrome A was degraded in etiolated seedlings with kinetics similar to those of endogenous rice phytochromes (half-life approximately 20 min). Although plants overexpressing phytochrome A were phenotypically indistinguishable from wild-type plants when grown under high-fluence white light, they were more sensitive as etiolated seedlings to light pulses that established very low phytochrome equilibria. This indicates that the introduced oat phytochrome A was biologically active. Thus, rice ectopically expressing PHY genes may offer a useful model to help understand the physiological functions of the various phytochrome isoforms in monocotyledonous plants.     

Possible role of light in the maintenance of EIN3/EIL1 stability in Arabidopsis seedlings

To examine the mechanism of EIN3-mediated gene expression by ethylene, the expression patterns of ethylene-inducible genes by ethylene were monitored in Col-0 and ethylene signaling mutants. In Col-0, the inducibility of ACC oxidase by ethylene in light-grown seedlings was much higher than in dark-grown seedlings. While the expression of ACC oxidase was highly increased by ethylene not only in Col-0 but in ein3-1 under light treatment, this pattern was completely abrogated in etiolated ein3-1 seedlings, suggesting the expression of EIN3-mediated ACC oxidase genes could be affected by light. To check if the level of EIN3 and EIL1 was regulated by light, cell-free degradation assays were performed. This resulted in the rapid degradation of these proteins within 1h after adding dark-grown cell extracts and this degradation was retarded by light-grown extracts. Here, we propose that light may act as a negative regulator in the destabilization of EIN3/EIL1.