Phytochrome in the Fern, Adiantum capillus-veneris L.: Spectrophotometric Detection in Vivo and Partial Purification

Spectrophotometric studies of fern phytochrome were performedusing dark-grown leaves of Adiantum. The absorbance differencespectrum between the red- and far-red-light irradiated sampleshowed a photoreversible absorbance change in the far-red region,with a maximum located at 728–730 nm. The concentrationof phytochrome was highest at the leaf tips and decreased graduallyalong the leaf axis. As in the case of angiosperm phytochrome,the level of fern phytochrome decreased under continuous whitelight, and the level increased again when deetiolated tissuewas transferred back to the dark. When the fern tissue was exposedto a pulse of red light, the dark reversion of P_FR to P_R tookplace with almost no destruction of P_FR. Phytochrome could beextracted from light-grown young leaves of the fern with a slightlyalkaline, aqueous buffer that contained 1 M NaCl. The differencespectrum of the partially purified phytochrome from fern wassimilar to that of partially degraded phytochrome from angio-sperms.A polyclonal antibody raised against phytochrome from etiolatedrye seedlings immuno-stained (albeit weakly) a 110-kDa polypeptideafter fractionation by SDS-polyacrylamide gel electrophoresisof the preparation of fern phytochrome. The band was very probablyfern phytochrome since it emitted zinc-induced fluorescence. (Received July 12, 1990; Accepted October 5, 1990)     

Stable concentrations of phytochrome in pisum under continuous illumination with red light

In vivo spectrophotometry showed that the phytochrome concentration in pea epicotyl hooks decreased at a constant rate for 4 hours when the tissue was exposed to continuous red light. Thereafter the rate slowed progressively so that a steady concentration of phytochrome was approached at hour 7. Returning the plants to darkness resulted in an increase in phytochrome due to the apparent synthesis of P_R. A closely similar pattern of changes was found in the amount of phytochrome extracted from the tissue. The establishment of the stable concentration was inhibited by 2,4-dichlorophenoxyacetic acid and did not occur in segments which had been incubated for longer than 24 hours, but was observed when segment growth was inhibited by mannitol. The results may be explained by an equilibrium between P_FR destruction and apparent P_R synthesis.     

Differences in Photoresponse and Phytochrome Spectrophotometry Between Etiolated and De-etiolated Pea Stem Tissue

Morphologically similar pea plants having a 4-fold difference in spectrophoto-metrically detectable phytochrome can be produced by pretreatment of etiolated plants with red light (R) or with red and far-red light combined (RF). A search for response differences which could be ascribed to differences in phytochrome content has resulted only in the establishment of differences due to de-etiolation. Segments of etiolated plants differ from those of plants de-etiolated by R and RF pretreatments in 2 ways. Segments from etiolated plants appear to respond rapidly to the far-red absorbing form of phytochrome (P_FR), while segments from de-etiolated plants do not respond rapidly to P_FR. This statement is based upon 2 observations: (i) the red light induced growth inhibition in segments from etiolated plants rapidly escapes reversibility by far-red light, while with segments from R or RF pretreated plants, the red light effect is fully reversed by subsequent far-red light for up to 2 hr; and (ii) segments from etiolated plants were inhibited to a greater degree than were segments from RF pretreated plants when various photostationary state levels of P_FR were maintained for 30 or 90 min and then removed by photoconversion to P_R. The in vivo nonphotochemical transformation curves of the phytochrome of etiolated and RF pretreated plants appear to differ in 2 related respects: (i) the amount of phytochrome destroyed in de-etiolated tissue is greater than that in etiolated tissue, perhaps as a result of the fact that (ii) the rate and extent of apparent reversion of P_FR to P_R in etiolated tissue is about twice that in de-etiolated tissue.     

Phytochrome and Seed Germination. IV. Action of Light Sources With Different Spectral Energy Distribution on the Germination of Tomato Seeds

Germination of tomato seeds exposed to a single, saturating irradiation from light sources of different spectral energy distribution seems to be dependent upon the photostationary P_FR/P_R ratio established by the irradiation. Germination of tomato seeds exposed to prolonged irradiations from the same light sources does not seem to be controlled solely by the P_FR/P_R ratio induced and maintained by the irradiation.     

Aspects of phytochrome decay in etiolated seedlings under continuous Illumination

Summary The rate of total phytochrome decay in the dicotyledons Amaranthus caudatus, Mirabilis jalapa and Pisum sativum under continuous illumination with red, incandescent, and blue light depends on the P_FR/P_total maintained by each source. Amaranthus is an exception to this in that there is a deviation from firstorder decay kinetics under continuous illumination with incancdescent light. This deviation is probably not related to the chlorophyll present in the Amaranthus sample since chlorophyll-rich Pisum buds have the same phytochrome decay rate as epicotyl tissue under continuous incandescent light. Reports of a prolonged lag phase before the onset of first-order decay kinetics of phytochrome in Pisum have not been confirmed and the small lag phase observed in the present work can be accounted for by the time required to attain the P_FR/P_total ratio characteristic of blue light in a carotenoid rich tissue. In the monocotyledon, Avena sativa, and perhaps monocotyledons in general, decay rate is maximal at a low P_FR concentration and the decay curve is the same under continuous red, incandescent and blue light. This dicotyledon/monocotyledon difference with respect to saturation of phytochrome decay does not correlate with the other dicotyledon/monocotyledon difference, the presence or absence of dark reverions of P_FR to P_R, since the dicotyledons Amaranthus and Mirabilis that lack reversion still show no saturation of decay. Possible growth control by the P_FR/P_total ratio is discussed in relation to environmental changes in light quality.Research carried out at Brookhaven National Laboratory under the auspices of the U. S. Atomic Energy Commission.     

Response of tissue with different phytochrome contents to various initial photostationary States

Pretreatment of etiolated pea plants with red light and with red combined with far-red light produced morphologically similar plants having 4-fold differences in spectrophotometrically detectable phytochrome. Stem segments from the variously pretreated plants respond in the same way to different percentage conversions of phytochrome to P_FR. These results suggest that the P_FR./P_R ratio, rather than the concentration of P_FR, governs pea stem segment elongation. However, the ratio hypothesis does not explain contradictions between spectrophotometric and physiological assays previously obtained with this tissue, nor does it explain similar contradictions obtained in other systems. The only hypothesis consistent with the data to date is that of the existence of bulk and active phytochrome fractions, with the latter present in insufficient quantities to be spectrophotometrically detectable.     

Long-lived Intermediates in Phytochrome Transformation II: In Vitro and In Vivo Studies

Conditions of illumination which cause phytochrome to cycle rapidly from P_R to P_FR and back lead to the accumulation in vivo of detectable amounts of long-lived intermediates on the P_R to P_FR pathway in oat coleoptile tissue. They appear to decay independently and in parallel to P_FR. Their behavior under different intensities of illumination and exposure time suggests that they are homologous with 2 similar intermediates previously observed in vitro. Available evidence favoring this suggestion is discussed. Equivalent illumination apparently causes far higher steady state levels of absorption by intermediates in vivo than in vitro, suggestion that native phytochrome is in a different physical state in the cell than it is in solution. A difference spectrum for the intermediates in vitro between 365 and 580 nm is presented. It has a maximum at 380 nm, a minimum at 418 nm, and crossover points at 398 and 485 nm. Glycerol in the phytochrome sample enhances the signal without otherwise changing the spectrum in any way. The difference spectrum represents the difference in absorption between the combined intermediates and P_FR.     

Isolation of phytochrome from the alga mesotaenium and liverwort sphaerocarpos

Phytochrome has been isolated from the green alga Mesotaenium and the liverwort Sphaerocarpos. The Mesotaenium pigment had absorption peaks at 649 and 710 nm for the P_R and P_FR forms, respectively. Corresponding difference spectrum maxima for the Sphaerocarpos pigment were at 655 and 720 nm. While the absorption maxima differ, the reversibility and efficiency with which red and far-red light transform the Mesotaenium pigment are very similar to that reported for phytochrome isolated from etiolated seedlings of higher plants. Methods are described which allow efficient separation of phytochrome from highly pigmented light-grown material.     

PHYTOCHROME CHANGES IN TISSUES OF DARK-GROWN SEEDLINGS REPRESENTING VARIOUS PHOTOPERIODIC CLASSES

Excised tissues of dark-grown seedlings representing long day, short day and daylength indifferent photoperiodic classes were assayed for nonphotochemical changes in phytochrome. In all tissues tested, these changes were qualitatively the same. A brief irradiation with red light was followed in darkness by a decrease in total phytochrome, the disappearance of P_FR, and an increase in detectable P_R. Within the limits of the tissues tested, the kinetics of phytochrome change can be assigned to three groups on the basis of rates. These groups are represented by coleoptiles, hypocotyls and epicotyls, and mesocotyls. The kinetics could not be distinguished on the basis of the photoperiodic class of the mature plant. The significance of these kinetics with respect to the photochemistry of phytochrome conversion is discussed.     

Some Properties of Phytochrome Isolated From Dark-grown Oat Seedlings (Avena sativa L.)

Phytochrome was partially purified from etiolated seedlings of Avena sativa L. Several properties of the red-absorbing (P_R) and far-red absorbing (P_FR) forms of the pigment were compared. The 2 forms could not be shown to differ with respect to their sedimentation velocity in sucrose density gradients, elution volume from Sephadex G-200 columns, binding properties on calcium phosphate, or electrophoretic mobility. P_FR, however, was more labile than P_R during precipitation with 50% ammonium sulfate. Sephadex G-200 elution diagrams obtained with fresh phytochrome preparations revealed 2 components of different molecular weights, 1 roughly 180,000, and 1 roughly 80,000. Native phytochrome had an absorption spectrum in vivo showing an absorption maximum for P_R of 667 nm. Both the large and small forms of phytochrome mentioned above can be maintained with an absorption maximum for P_R of 667 nm. However, allowing them to remain for several hours as P_FR, even at 4°, shifted this peak to 660 nm. The protein conformational change during phytochrome transformation may be quite small, though the various comparative techniques used do not strictly rule out a fairly large one. The need for maintaining the pigment as P_R during all steps of purification, but particularly during ammonium sulfate precipitation is underscored.     

Long-lived Intermediates in Phytochrome Transformation I: In Vitro Studies

Irradiation of phytochrome solutions with a high-intensity mixed red and far red light source causes measurable absorbancy increases at 543 nm. Evidence is presented that these absorbancy increases are caused by accumulation of intermediates on the P_R to P_FR pathway with relatively slow thermal decay constants. Kinetic analysis of the decay signals is consistent with the interpretation that the signals represent simultaneous independent and parallel decay of 2 species by first order kinetics to P_FR. If actinic light intensity is kept constant and exposure time changed, the relative amounts of the 2 components change, with proportionately more of the rapidly decaying species present following short exposure times. If the amount of the intermediates is decreased by decreasing actinic light intensity at constant exposure time, however, the relative amounts of the 2 remain constant. The Q₁₀ for intermediate decay following illumination is approximately 2.0, while that for complete phototransformation of the pigment in either direction is very close to 1.0. Incomplete transformation of P_R to P_FR, caused by overlapping absorption of the 2 forms, is shown by the presence of intermediates (indicating cycling of the pigment) in continuous red light. Such intermediates do not appear in continuous far red, indicating a rate of pigment cycling below detection by the available instrumentation.     

Differences between the Surface Properties of the PR and PFR Forms of Native Pea Phytochrome, and Their Application to a Simplified Procedure for Purification of the Phytochrome

The ability of phytochrome from etiolated pea shoots (Pisumsativum L. cv. Alaska) to bind to various chromatographic adsorbentsand its mobility during non-denaturing electrophoresis wereexamined with phytochrome in either the red light-absorbingform (PR) or the far-red light-absorbing form (P_FR). Preferentialbinding of P_FR to modified hydrophilic polyvinyl resins, suchas butyl Toyopearl, phenyl Toyopearl, Blue Toyopearl (CibacronBlue F3G-A conjugated) and Red Toyopearl (Procion Red HE-3Bconjugated), was observed. A simplified method for purificationof native phytochrome was developed based on the propertiesof P_R and P_FR. P_FR bound preferentially to the hydrophobic adsorbents,to indicate that the surface of P_FR is more hydrophobic thanthat of P_R. A difference in net surface charges between P_R andP_FR was detected by an analysis based on the different mobilitiesof the two forms during non-denaturing polyacrylamide gel electrophoresisin gels prepared with various concentrations of polyacrylamide.The apparent molecular weights of P_R and P_FR, estimated fromthe analysis, were 378 and 419 kilodaltons, respectively. Thedifference suggests that a significant change in molecular shapeoccurs during the photoconversion. The differences in surfaceproperties of P_R and P_FR are discussed. (Received April 20, 1991; Accepted August 26, 1991)     

Photosynthetic ability in dark-grown Reboulia hemisphaerica and Barbula unguiculata cells in suspension culture

Suspension cultured cells of the liverwort, Reboulia hemisphaerica and of the moss, Barbula unguiculata were independently subcultured in the medium containing 2% glucose in the dark or in the light for more than one year, and the photosynthetic activities of the final cultures were determined. Throughout the culture period light-grown cells of both species contained high amount of chlorophyll (4 to 34 g mg^–1 dry weight) and showed a high photosynthetic activity (10 to 84 mol O₂ mg^–1 chlorophyll h^–1). Dark-grown cells of R. hemisphaerica showed the same level of chlorophyll content and photosynthetic O₂ evolving activity as light-grown cells. Although chlorophyll content in dark-grown B. unguiculata cells was ten-fold lower than that in light-grown cells, the photosynthetic activity of these dark-grown cells was higher than that of light-grown cells based on chlorophyll content.     

Phototaxis in a dinoflagellate: Action spectra as evidence for a two-pigment system

Summary Action spectra were determined in the UV region of the spectrum for the first phase of the phototactic response (stop response) and for the phytochrome pigment associated with this response in the dinoflagellate Gyrodinium dorsum Kofoid. Differences between these action spectra indicate the participation of two pigments in phototaxis. Following R (620 nm) irradiation of the phytochrome, the stop response maxima occur at 470 and 280-nm; after FR irradiation they shift to 490 and 300–310 nm. These maxima suggest that the photoreceptor pigment for phototaxis is a carotenoprotein. The action spectrum shift following the different phytochrome conversions may represent a trans to cis isomer change by the carotenoid. The absorption maximum of P_R in the UV appears to be at 320 nm, which is consistent with the shift of the R absorption maximum to shorter wavelengths (620 nm) as compared to higher plants. The P_FR absorption maximum appears as a broad band between 360 and 390 nm. Comparison of P_R to P_FR conversions by different intensities of 620-nm and 320-nm light indicates that at lower intensities the logarithm of the threshold for the stop response is inversely proportional to the logarithm of the intensity of the sensitizing light. The ratio of response activation by R and UV light is about 4:1.Abbreviations FR far-red - R red - P_FR far-red-absorbing form of phytochrome - P_R red-absorbing form of phytochrome - UV ultraviolet     

Phototransformation of the Red-Light-Absorbing Form to the Far-Red-Light-Absorbing Form of Phytochrome in Pea Epicotyl Tissue Measured by a Multichannel Transient Spectrum Analyser

Phototransformation of the red-light-absorbing form (P_R) tothe far-red-light-absorbing form (P_FR) of phytochrome in 7-day-oldetiolated pea epicotyl hook segments was examined at 0.5C aftera red laser flash excitation using a multichannel transientspectra analyser with electrically gated photomultiplier. Effectsof a red laser pulse on the induction of phototransformationfrom P_R to P_FR were saturated at Ca. 15 mJ for flash wavelengthsof both 640 and 655 nm. The amount of P_FR induced by a saturatinglaser pulse was ca. 50% of that obtained at the photostationaryequilibrium. A difference spectrum measured 15 µs afterthe flash showed an absorbance increase at 697 nm and a decreaseat 663 nm. A difference spectrum determined 200 ms after theflash showed no such major absorbance increase. Kinetic analysisof the rapid absorbance decrease at 700 and 710 nm gave onesimple first-order reaction component having a rate constantof 2,500 s^–1. Kinetics of P_FR appearance measured by absorbanceincrease at 750 nm was resolved into three first-order reactionshaving rate constants of 5, 1.8 and 0.4 s^–1. The secondflash light of 710 nm given 2 µs and 2 ms after the firstred flash irradiation on P_R resulted in the formation of P_Rrather than P_FR. (Received February 8, 1985; Accepted April 11, 1985)     

The phytochrome system in light-grown Zea mays L.

The phytochrome system is analyzed in light-grown maize (Zea mays L.) plants, which were prevented from greening by application of the herbicide SAN 9789. The dark kinetics of phytochrome are not different in the first, second or third leaf. It is concluded that in light-grown maize plants phytochrome levels are regulated by P_r formation and P_fr and P_r destruction, rather than by P_frP_r dark reversion. P_r undergoes destruction after it has been cycled through P_fr. The consequences of this P_r destruction on the phytochrome system are discussed.Abbreviations SAN 9789 4-chloro-5-(methylamino)-2-(,,-trifluoro-m-tolyl)-3(2H) pyridazinone - P_fr far-red absorbing form of phytochrome - P_r red absorbing form of phytochrome - P_tot P_fr+P_r     

Binding Proteins to Phytochrome A in Etiolated Pea Seedlings

In order to detect and characterize a putative receptor(s) fora signal from PhyA, proteins that bind to purified pea PhyAwere searched for in the crude extract of etiolated pea seedlingswith affinity chromatography. PhyA was coupled to the columnsubstrate either in P_R form (P_R column) or in red-irradiatedform (P_FR column). The coupled PhyA of both columns retainsits spectral reversibility between P_R and P_FR, although theirpeptide mapping by trypsin digestion suggests that the C-terminalhalf of PhyA in the P_FR column is partially fixed in P_FR structure.15 polypeptides were detected reproducibly in the elution fromthe P_FR column by silver-staining of SDS-PAGE. These 15 polypeptidesmay form two complexes judging from their elution profiles.Of the 15 polypeptides, the 6 major polypeptides have approximatemol wt of 80, 55, 53, 46, 40 and 35 kDa. On the other hand,only a trace amount of protein, which mainly consists of the46 kDa species, was eluted from P_R column, indicating the presenceof P_FR-specific BPs in the crude extract of etiolated pea seedlings.Of the 6 major polypeptides, the 40 kDa species binds to thePhyA in a photoreversible manner. (Received June 19, 1998; Accepted December 19, 1998)     

Levels of Indol-3yl-acetic Acid and Acid Inhibitors in Green and Etiolated Bean Seedlings (Phaseolus vulgaris)

Indol-3yl-acetic acid (IAA) was identified in Phaseolus vulgaris L. Shoot tissue of seedlings, exposed to light for 5 days, had a higher level of IAA than etiolated seedlings of the same age. The content of IAA increased in green seedlings during light treatment for 5–12 days. No increase could be measured in dark-grown seedlings. Inhibitory substances appeared at different R_f-values. The main part was identical to the inhibitor-β complex and occurred in a higher amount in light-grown seedlings than in etiolated taller ones. One part of the inhibitor-complex appeared to be abscisic acid (ABA). It is suggested that both IAA and acid inhibitors may play an important role in the control of stem growth and differentiation, although light effects on other hormones and regulatory systems cannot be ignored.     

Activity of NADPH-generating pathways in relation to polyketide synthesis in the fungusAlternaria alternata

The synthesis of the secondary metabolites, polyketides, by fungi has been proposed to be regulated by theNADPH/NADP> ratio, which determines whether acetyl units are incorporated into fatty acids or polyketides. In the moldAlternaria alternata synthesis of the polyketide alternariol is inhibited by light while lipid synthesis is enhanced compared with mycelia grown in darkness. The activity andK_m values of enzymes in NADPH-generating pathways were measured in dark-grown (polyketide-producing) and light-grown (nonproducing) mycelia ofA. alternata. Glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, mannitol-1-phosphate dehydrogenase, mannitol-1-phosphatase, and NADP-isocitrate dehydrogenase each had a similar specific activity andK_m in light- compared with dark-grown cultures at the time of onset of polyketide synthesis. NADP-mannitol dehydrogenase activity was two times higher in dark-grown than in light-grown mycelia. TheK_m (mannitol) for the enzyme and the mycelial mannitol content were the same. When incorporation of [¹⁴C[mannitol into lipids was measuredin vivo the rate of mannitol oxidation was similar in light and darkness. These results suggest that the NADPH-generating capacity is not reduced in dark-grown as compared with light-grownA. alternata.     

Photocontrol of anthocyanin formation in turnip seedlings

Summary The substitution of red or blue light for the first six hours of prolonged irradiation with far-red light reduced anthocyanin formation by about 60%; red or far-red light similarly substituted for blue light had little effect. It is concluded that the effects of prolonged irradiation with blue and far-red depend, in part at least, on different photoreceptors.The effects of pre-treatment with red or blue light also occurred when only short exposures to light were given, and were reversed by immediate brief exposures to far-red. The depressing effect of a short pre-irradiation treatment was largely prevented if seedlings were kept at low temperature or in an atmosphere of nitrogen in the dark period before transfer to the prolonged far-red treatment. The effect of the pre-irradiation treatment is attributed to enzymatic destruction of phytochrome following conversion to the P _FR form, and it is suggested that anthocyanin synthesis in far-red light largely depends on phytochrome, possibly due to the maintenance of a low level of P _FR in the tissue by the absorption tail of P _R in the far-red.A pre-irradiation treatment with red also decreased the inhibitory effect of far-red on hypocotyl elongation but did not change the response to blue light.

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Zusammenfassung Die Anthocyanbildung war im langfristig gegebenen Dunkelrot bis zu etwa 60% reduziert, wenn die ersten 6 Std durch hellrote oder blaue Bestrahlung ersetzt wurden; Hellrot oder Dunkelrot in gleicher Weise im Dauerblaulicht substituiert waren praktisch wirkungslos. Daraus wird geschlossen, daß der Effekt einer Dauerbestrahlung mit Blau und Dunkelrot zum Teil jedenfalls, auf verschiedene Photorezeptoren zurückzuführen ist.Der Effekt einer Vorbehandlung mit hellrotem oder blauem Licht trat auch dann auf, wenn nur kurzfristige Bestrahlungen gegeben wurden und konnte durch unmittelbar nachfolgende kurze Dunkelrot-Belichtung wieder aufgehoben werden. Die Hemmung durch kurzfristige Vorbestrahlung konnte weitgehend verhindert werden, wenn die Keimlinge während der Dunkelperiode, vor der Übertragung in Dauerdunkelrot, bei tiefer Temperatur oder unter Stickstoff gehalten wurden. Der Vorbelichtungseffekt wird auf die enzymatische Destruktion von Phytochrom, nach der Umwandlung in die P _FR -Form, zurückgeführt und es wird vermutet, daß die Anthocyansynthese im Dauerdunkelrot weitgehend phytochromabhängig ist, wahrscheinlich durch die Aufrechterhaltung eines niedrigen P _FR Niveaus im Gewebe infolge der schwachen Absorption von P _R im Dunkelrot.Eine Vorbelichtung mit Hellrot verringerte ebenfalls die hemmende Wirkung von Dunkelrot auf das Hypokotylwachstum, war jedoch ohne Einfluß im Blaulicht.