Influence of the Dietary Protein Deficiency on the Protein Synthetic Activity of Microsome and Soluble Fraction from Muscle and Liver of Rats

Phytochromes are photoreceptors that regulate many aspects of plant growth and development in response to red/far-red light signals from the environment. In this study, we analyzed chromophore ligation and photochromism of missense phytochrome mutants in the Per-Arnt-Sim (PAS)-related domain (PRD). Among the 14 mutants analyzed, the Gly768Asp mutant of Avena phytochrome A showed aberrant photochromism and dark reversion, suggesting that amino acid residues in the C-terminal domain affect the photochemical properties of the photosensory N-terminal domain.     

NDPK2 as a signal transducer in the phytochrome-mediated light signaling

Nucleoside-diphosphate kinase (NDPK) 2 in Arabidopsis has been identified as a phytochrome-interacting protein by using the C-terminal domain of phytochrome A (PhyA) as the bait in yeast two-hybrid screening. The far-red light-absorbing form of phytochrome (Pfr) A stimulates NDPK2 gamma-phosphate exchange activity in vitro. To better understand the multiple functions of NDPK and its role in phytochrome-mediated signaling, we characterized the interaction between phytochrome and NDPK2. Domain studies revealed that PER-ARNT-SIM domain A in the C-terminal domain of phytochrome is the binding site for NDPK2. Additionally, phytochrome recognizes both the NDPK2 C-terminal fragment and the NDPK2 hexameric structure to fulfill its binding. To illustrate the mechanism of how the Pfr form of phytochrome stimulates NDPK2, His-197-surrounding residue mutants were made and tested. Results suggested that the H-bonding with His-197 inside the nucleotide-binding pocket is critical for NDPK2 functioning. The pH dependence profiles of NDPK2 indicated that mutants with different activities from the wild type have different pK(a) values of His-197 and that NDPK2 hyperactive mutants possess lower pK(a) values. Because a lower pK(a) value of His-197 accelerates NDPK2 autophosphorylation and the phospho-transfer between the phosphorylated NDPK2 and its kinase substrate, we concluded that the Pfr form of phytochrome stimulates NDPK2 by lowering the pK(a) value of His-197.     

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.     

Missense mutation in the PAS2 domain of phytochrome A impairs subnuclear localization and a subset of responses

Phytochrome A signaling shows two photobiologically discrete outputs: so-called very-low-fluence responses (VLFR) and high-irradiance responses (HIR). By modifying previous screening protocols, we isolated two Arabidopsis mutants retaining VLFR and lacking HIR. Phytochrome A negatively or positively regulates phytochrome B signaling, depending on light conditions. These mutants retained the negative but lacked the positive regulation. Both mutants carry the novel phyA-302 allele, in which Glu-777 (a residue conserved in angiosperm phytochromes) changed to Lys in the PAS2 motif of the C-terminal domain. The phyA-302 mutants showed a 50% reduction in phytochrome A levels in darkness, but this difference was compensated for by greater stability under continuous far-red light. phyA-302:green fluorescent protein fusion proteins showed normal translocation from the cytosol to the nucleus under continuous far-red light but failed to produce nuclear spots, suggesting that nuclear speckles could be involved in HIR signaling and phytochrome A degradation. We propose that the PAS2 domain of phytochrome A is necessary to initiate signaling in HIR but not in VLFR, likely via interaction with a specific partner.     

Chromophore: apoprotein interactions in phytochrome A*

Phytochromes are molecular light switches by virtue of their photochromic red/far-red reversibility. The His-324 residue next to the chromophore-linked Cys-323 plays a critical role in conferring photochromism to the tetrapyrrole chromophore in native phytochrome A. The chromophore appears to be enclosed between the amphiphilic α-helical chains in a hydrophobic pocket. The absorbance maxima of both the Pr and the Pfr forms of pea phytochrome A are blue-shifted by 10 and 20 nm, respectively, upon C-terminal truncation. We speculate that the quaternary structure of the phytochrome A molecule involves some interactions of the C-terminal half with the chromophore domain. The Pfr conformation of phytochrome includes an amphiphilic α-helix of the amino terminal chain, which occurs in 113 ms after picosecond photoisomerization of the Pr form. Compared to α-helical folding, unfolding of the α-helix occurs faster in about 310 μs upon phototransformation of the Pfr form of phytochrome A. The photochromic transformation of phytochrome A modulates protein kinase-catalysed phosphorylation sites in vivo and in vitro, but only a subtle local change in conformation is detectable in the phosphorylated phytochromes. This suggests that the post-translational modification serves as a surface label, rather than a transducer-activating trigger, for the recognition of a putative phytochrome receptor.     

A new type of mutation in phytochrome A causes enhanced light sensitivity and alters the degradation and subcellular partitioning of the photoreceptor

A specific light program consisting of multiple treatments with alternating red and far-red light pulses was used to isolate mutants in phytochrome A-dependent signal transduction pathways in Arabidopsis. Because of their phenotype, the mutants were called eid for empfindlicher im dunkelroten Licht, which means hypersensitive in far-red light. One of the isolated mutants, eid4, is a novel semi-dominant allele of the phytochrome A gene that carries a missense mutation in the chromophore-binding domain. The mutation did not change the photochemical properties of the photoreceptor, but it leads to an increased stability under light conditions that induce its rapid degradation. Fusion proteins with the green fluorescent protein exhibited clear alterations in subcellular localization of the mutated photoreceptor: The fusion protein was impaired in the formation of sequestered areas of phytochrome in the cytosol, which can explain its reduced light-dependent degradation. In contrast, the mutation stabilizes nuclear speckles (NUS) that appear late under continuous far-red light, whereas the formation of early, transiently appearing NUS remained more or less unaltered.     

Carboxy-terminal deletion analysis of oat phytochrome A reveals the presence of separate domains required for structure and biological activity.

A series of seven carboxy-terminal deletion mutants of oat phytochrome A were stably expressed in transgenic tobacco to localize phytochrome domains involved in chromophore attachment, spectral integrity, photoreversibility between the red light (Pr)- and far-red light (Pfr)-absorbing forms, dimerization, and biological activity. Amino acids necessary for chromophore attachment in vivo were localized to the amino-terminal 398 residues because mutant proteins this small had covalently bound chromophore. Deletion mutants from the carboxy terminus to residue 653 were spectrally indistinguishable from the full-length chromoprotein. In contrast, further truncation to residue 399 resulted in a chromoprotein with a bleached Pfr absorbance spectrum, Pr and Pfr absorbance maxima shifted toward shorter wavelengths, and reduced Pfr to Pr phototransformation efficiency. Thus, residues between 399 ad 652 are required for spectral integrity but are not essential for chromophore attachment. The sequence(s) between residues 919 and 1093 appears to be necessary for dimerization. Carboxy-terminal mutants containing this region behaved as dimers under nondenaturing conditions in vitro, whereas truncations without this region behaved as monomers. None of the plants expressing high levels of deletion mutants lacking the 35 carboxy-terminal amino acids displayed the light-exaggerated phenotype characteristic of plants expressing biologically active phytochrome A, even when the truncated phytochromes were expressed at levels 6- to 15-fold greater than that effective for the full-length chromoprotein. Collectively, these data show that the phytochrome protein contains several separable carboxy-terminal domains required for structure/function and identify a domain within 35 residues of the carboxy terminus that is critical for the biological activity of the photoreceptor in vivo.     

Characterization of a novel non-constitutive photomorphogenic cop1 allele

A specific light program consisting of multiple treatments with alternating red and far-red light pulses was used to isolate mutants in phytochrome A-dependent signal transduction in Arabidopsis seedlings. Because of their phenotype, the mutants were called eid (empfindlicher im dunkelroten Licht, which means hypersensitive in far-red light). One of the isolated mutants, eid6, is a novel recessive allele of the COP1 gene (constitutive photomorphogenic 1) that carries an amino acid transition in a conserved histidine residue of the RING finger domain. Mutant seedlings exhibited an extreme hypersensitivity towards all tested light qualities, but in contrast to known cop1 alleles, no constitutive photomorphogenic phenotype was detectable in darkness. Thus, the novel cop1eid6 allele seems to encode for a protein whose remaining activity is sufficient for the suppression of photomorphogenesis in dark-grown plants. In adult cop1eid6 plants, the development of the Cop1 phenotype is dominated by phytochrome B. Comparison of the phenotype of the novel cop1eid6 and the weak cop1-4 allele under continuous far-red light indicates that the RING finger and coiled-coil domains of COP1 are sufficient for some specific regulatory function in phytochrome A-dependent high irradiance responses.     

Mutant screen distinguishes between residues necessary for light-signal perception and signal transfer by phytochrome B

The phytochromes (phyA to phyE) are a major plant photoreceptor family that regulate a diversity of developmental processes in response to light. The N-terminal 651-amino acid domain of phyB (N651), which binds an open tetrapyrrole chromophore, acts to perceive and transduce regulatory light signals in the cell nucleus. The N651 domain comprises several subdomains: the N-terminal extension, the Per/Arnt/Sim (PAS)-like subdomain (PLD), the cGMP phosphodiesterase/adenyl cyclase/FhlA (GAF) subdomain, and the phytochrome (PHY) subdomain. To define functional roles for these subdomains, we mutagenized an Arabidopsis thaliana line expressing N651 fused in tandem to green fluorescent protein, beta-glucuronidase, and a nuclear localization signal. A large-scale screen for long hypocotyl mutants identified 14 novel intragenic missense mutations in the N651 moiety. These new mutations, along with eight previously identified mutations, were distributed throughout N651, indicating that each subdomain has an important function. In vitro analysis of the spectral properties of these mutants enabled them to be classified into two principal classes: light-signal perception mutants (those with defective spectral activity), and signaling mutants (those normal in light perception but defective in intracellular signal transfer). Most spectral mutants were found in the GAF and PHY subdomains. On the other hand, the signaling mutants tend to be located in the N-terminal extension and PLD. These observations indicate that the N-terminal extension and PLD are mainly involved in signal transfer, but that the C-terminal GAF and PHY subdomains are responsible for light perception. Among the signaling mutants, R110Q, G111D, G112D, and R325K were particularly interesting. Alignment with the recently described three-dimensional structure of the PAS-GAF domain of a bacterial phytochrome suggests that these four mutations reside in the vicinity of the phytochrome light-sensing knot.     

Missense mutations define a restricted segment in the C-terminal domain of phytochrome A critical to its regulatory activity.

The phytochrome family of photoreceptors has dual molecular functions: photosensory, involving light signal perception, and regulatory, involving signal transfer to downstream transduction components. To define residues necessary specifically for the regulatory activity of phytochrome A (phyA), we undertook a genetic screen to identify Arabidopsis mutants producing wild-type levels of biologically defective but photochemically active and dimeric phyA molecules. Of eight such mutants identified, six contain missense mutations (including three in the same residue, glycine 727) clustered within a restricted segment in the C-terminal domain of the polypeptide. Quantitative photobiological analysis revealed retention of varying degrees of partial activity among the different alleles--a result consistent with the extent of conservation at the position mutated. Together with additional data, these results indicate that the photoreceptor subdomain identified here is critical to the regulatory activity of both phyA and phyB.     

The effect of daylength on the transition to flowering in phytochrome-deficient, late-flowering and double mutants of Arabidopsis thaliana

The effect of daylength on flowering was investigated in the following mutants of Arabidopsis thaliana : phytochrome B deficient ( hy3=phyB ); phytochrome chromophore deficient ( hy2 ); late-flowering ( co, gi. fca and fwa ); the hy2 and hy3 , late-flowering double mutants and the hy2, hy3 , late-flowering triple mutants. The hy mutants flower with fewer rosette leaves than the Landsberg erecta wild type under both long day and short day conditions and express this effect to a different degree in all late-flowering mutant backgrounds and under both daylengths, with the exception of fca under short days. The number of cauline leaves and days to flowering is less affected by the hy genotype. The hy2, hy3 double mutants flower with even fewer rosette leaves than the hy2 and hy3 monogenic mutants, suggesting an inhibitory role for phytochrome B and other stable phytochromes on flowering. The complex interaction between phytochrome, daylength and the effect of the late-flowering genes on the various parameters that describe the transition to flowering in Arabidopsis is discussed.     

Effect of Light on Root Hair Formation in Arabidopsis thaliana Phytochrome-Deficient Mutants

Arabidopsis thaliana lacking phytochrome A, phytochrome B or both (double mutant) were analyzed by comparing their photoresponse with that of the wild type. Results indicate that root hair formation in Arabidopsis was strongly stimulated by light irradiation. Both phytochrome A and phytochrome B are responsible for photoinduction by continuous red light irradiation, while only phytochrome A mediates the response under continuous far-red light. The fluence response relationships to a red light pulse in the wild type displayed a biphasic trend similar to that previously observed in lettuce seedlings, with the first phase showing a sharp maximum at 78.3 Jm⁻², and the second one operating over a wider fluence range (3,100–9,400 Jm⁻²) two orders of magnitude higher than the first one. Analysis of the fluence response curves for red light induction in the phytochrome mutants revealed that phytochrome A is responsible for the first phase in the wild type, while the second is the result of the combined action of both phytochrome A and phytochrome B. Received 13 August 1999/ Accepted in revised form 22 December 1999     

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.     

Flowering responses to altered expression of phytochrome in mutants and transgenic lines of Arabidopsis thaliana (L.) Heynh.

The long-day plant Arabidopsis thaliana (L.) Heynh. flowers early in response to brief end-of-day (EOD) exposures to far-red light (FR) following a fluorescent short day of 8 h. FR promotion of flowering was nullified by subsequent brief red light (R) EOD exposure, indicating phytochrome involvement. The EOD response to R or FR is a robust measure of phytochrome action. Along with their wild-type (WT) parents, mutants deficient in either phytochrome A or B responded similarly to the EOD treatments. Thus, neither phytochrome A nor B exclusively regulated flowering, although phytochrome B controlled hypocotyl elongation. Perhaps a third phytochrome species is important for the EOD responses of the mutants and/or their flowering is regulated by the amount of the FR-absorbing form of phytochrome, irrespective of the phytochrome species. Overexpression of phytochrome A or phytochrome B resulted in differing photoperiod and EOD responses among the genotypes. The day-neutral overexpressor of phytochrome A had an EOD response similar to all of the mutants and WTs, whereas R EOD exposure promoted flowering in the overexpressor of phytochrome B and FR EOD exposure inhibited this promotion. The comparisons between relative flowering times and leaf numbers at flowering of the over-expressors and their WTs were not consistent across photoperiods and light treatments, although both phytochromes A and B contributed to regulating flowering of the transgenic plants.     

Different Roles for Phytochrome in Etiolated and Green Plants Deduced from Characterization of Arabidopsis thaliana Mutants

We have isolated a new complementation group of Arabidopsis thaliana long hypocotyl mutant (hy6) and have characterized a variety of light-regulated phenomena in hy6 and other previously isolated A. thaliana hy mutants. Among six complementation groups that define the HY phenotype in A. thaliana, three (hy1, hy2, and hy6) had significantly lowered levels of photoreversibly detectable phytochrome, although near wild-type levels of the phytochrome apoprotein were present in all three mutants. When photoregulation of chlorophyll a/b binding protein (cab) gene expression was examined, results obtained depended dramatically on the light regime employed. Using the red/far-red photoreversibility assay on etiolated plants, the accumulation of cab mRNAs was considerably less in the phytochrome-deficient mutants than in wild-type A. thaliana seedlings. When grown in high-fluence rate white light, however, the mutants accumulated wild-type levels of cab mRNAs and other mRNAs thought to be regulated by phytochrome. An examination of the light-grown phenotypes of the phytochrome-deficient mutants, using biochemical, molecular, and morphological techniques, revealed that the mutants displayed incomplete chloroplast and leaf development under conditions where wild-type chloroplasts developed normally. Thus, although phytochrome may play a role in gene expression in etiolated plants, a primary role for phytochrome in green plants is likely to be in modulating the amount of chloroplast development, rather than triggering the initiation of events (e.g., gene expression) associated with chloroplast development.     

The Signaling Mechanism of Arabidopsis CRY1 Involves Direct Interaction with COP1

Dark-grown transgenic Arabidopsis seedlings expressing the C-terminal domains (CCT) of the cryptochrome (CRY) blue light photoreceptors exhibit features that are normally associated only with light-grown seedlings, indicating that the signaling mechanism of Arabidopsis CRY is mediated through CCT. The phenotypic properties mediated by CCT are remarkably similar to those of the constitutive photomorphogenic1 (cop1) mutants. Here we show that Arabidopsis cryptochrome 1 (CRY1) and its C-terminal domain (CCT1) interacted strongly with the COP1 protein. Coimmunoprecipitation studies showed that CRY1 was bound to COP1 in extracts from both dark- and light-grown Arabidopsis. An interaction also was observed between the C-terminal domain of Arabidopsis phytochrome B and COP1, suggesting that phytochrome signaling also proceeds, at least in part, through direct interaction with COP1. These findings give new insight into the initial step in light signaling in Arabidopsis, providing a molecular link between the blue light receptor, CRY1, and COP1, a negative regulator of photomorphogenesis.     

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     

New lv Mutants of Pea Are Deficient in Phytochrome B

The lv-1 mutant of pea (Pisum sativum L.) is deficient in responses regulated by phytochrome B (phyB) in other species but has normal levels of spectrally active phyB. We have characterized three further lv mutants (lv-2, lv-3, and lv-4), which are all elongated under red (R) and white light but are indistinguishable from wild type under far-red light. The phyB apoprotein present in the lv-1 mutant was undetectable in all three new lv mutants. The identification of allelic mutants with and without phyB apoprotein suggests that Lv may be a structural gene for a B-type phytochrome. Furthermore, it indicates that the lv-1 mutation results specifically in the loss of normal biological activity of this phytochrome. Red-light-pulse and fluence-rate-response experiments suggest that lv plants are deficient in the low-fluence response (LFR) but retain a normal very-low-fluence-rate-dependent response for leaflet expansion and inhibition of stem elongation. Comparison of lv alleles of differing severity indicates that the LFR for stem elongation can be mediated by a lower level of phyB than the LFR for leaflet expansion. The retention of a strong response to continuous low-fluence-rate R in all four lv mutants suggests that there may be an additional phytochrome controlling responses to R in pea. The kinetics of phytochrome destruction and reaccumulation in the lv mutant indicate that phyB may be involved in the light regulation of phyA levels.