Genetic Regulation of Development in Sorghum bicolor: VI. The ma(3) Allele Results in Abnormal Phytochrome Physiology

Physiological processes controlled by phytochrome were examined in three near-isogenic genotypes of Sorghum bicolor, differing at the allele of the third maturity gene locus. Seedlings of 58M (ma₃^R ma₃^R) did not show phytochrome control of anthocyanin synthesis. In contrast, seedlings of 90M (ma₃ma₃) and 100M (Ma₃Ma₃) demonstrated reduced anthocyanin synthesis after treatment with far red and reversal of the far red effect by red. De-etiolation of 48-hour-old 90M and 100M dark-grown seedlings occurred with 48 hours of continuous red. Dark-grown 58M seedlings did not de-etiolate with continuous red treatment. Treatment of seedlings with gibberellic acid or tetcyclacis, a gibberellin synthesis inhibitor, did not alter anthocyanin synthesis. Levels of chlorophyll and anthocyanin were lower in light-grown 58M seedlings than in 90M and 100M. Etiolated seedlings of all three genotypes have similar amounts of photoreversible phytochrome. Crude protein extracts from etiolated seedlings were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transferred to nitrocellulose. Phytochrome was visualized with Pea-25, a monoclonal antibody directed to phytochrome from etiolated peas. The samples from all three genotypes contained approximately equivalent amounts of a prominent, immunostaining band at 126 kD. However, the sample from 58M did not show a fainter, secondary band at 123 kD that was present in 90M and 100M. The identity and importance of this secondary band at 123 kD is unknown. We propose that 58M is a phytochrome-related mutant that contains normal amounts of photoreversible phytochrome and normal phytochrome protein when grown in the dark.     

Altered Phytochrome Regulation of Greening in an aurea Mutant of Tomato

A brief pulse of red light accelerates chlorophyll accumulation upon subsequent transfer of dark-grown tomato (Lycopersicon esculentum) seedlings to continuous white light. Such potentiation of greening was compared in wild type and an aurea mutant W616. This mutant has been the subject of recent studies of phytochrome phototransduction; its dark-grown seedlings are deficient in phytochrome, and light-grown plants have yellow-green leaves. The rate of greening was slower in the mutant, but the extent (relative to the dark control) of potentiation by the red pulse was similar to that in the wild type. In the wild type, the fluence-response curve for potentiation of greening indicates substantial components in the VLF (very low fluence) and LF (low fluence) ranges. Far-red light could only partially reverse the effect of red. In the aurea mutant, only red light in the LF range was effective, and the effect of red was completely reversed by far-red light. When grown in total darkness, aurea seedlings are also deficient in photoconvertible PChl(ide). Upon transfer to white light, the aurea mutant was defective in both the abundance and light regulation of the light-harvesting chlorophyll a/b binding polypeptide(s) [LHC(II)]. The results are consistent with the VLF response in greening being mediated by phytochrome. Furthermore, the data support the hypothesis that light modulates LHC(II) levels through its control of the synthesis of both chlorophyll and its LHC(II) apoproteins. Some, but not all, aspects of the aurea phenotype can be accounted for by the deficiency in photoreception by phytochrome.     

Turnover of phytochrome in pumpkin cotyledons

By using density labeling, it was found that the protein moiety of phytochrome is synthesized de novo in the red-absorbing form in cotyledons of dark-grown pumpkin (Cucurbita pepo L.) seedlings, as well as those irradiated with red light and returned to the dark. The rate of synthesis appears to be unaffected by the light treatment. Turnover of the red-absorbing form was also detected in dark grown seedlings using density labeling, while turnover of the far red-absorbing form is already implied from the well known “destruction” observed in irradiated seedlings. In both cases, true degradation of the protein is involved, but the rate constant of degradation of the far red-absorbing form may be up to two orders of magnitude greater than that of the red-absorbing form. The data indicate that, in pumpkin cotyledons, phytochrome levels are regulated against a background of continuous synthesis through divergent rate constants of degradation of the red and far red-absorbing forms and the relative proportions of the two forms present.     

Über den Einfluß von Licht auf den Umsatz der Isoflavone Formononetin und Biochanin A in Cicer arietinum L.

Summary The effect of different light conditions (white, red, far-red) and darkness on the accumulation of the isoflavones biochanin A and formononetin in Cicer arietinum L. were determined. The phytochrome system was shown not to stimulate the biosynthesis of these products. To differentiate between simultaneous synthesis and turnover of isoflavones, experiments using DL-phenylalanine-(I-¹⁴C) as precursor were performed with dark and far-red grown seedlings. The results indicate that the active phytochrome (P _fr ) inhibits isoflavone synthesis, presumably at a late stage, and also prevents further turnover. In dark grown plants both synthesis and turnover were found to take place. The results are discussed on the basis of the assumption that more than one isoflavone pool may have been involved. The percent distribution of biochanin A and formononetin in different plant organs was determined and the results are discussed in relation to isoflavone metabolism.

---

---

Stoffwechsel aromatischer Pflanzeninhaltsstoffe. IV.     

Amplification of phytochrome induced morphogenesis in plants by the cryptic red light signal (CRS)

The regulation of endogenous levels of ascorbic acid in soybean by far-red absorbing form of phytochrome (Pfr) and by cryptic red light signal (CRS) was studied. Cryptic red light signal is produced by red light pre-irradiation of a photoreceptor other than far-red absorbing form of phytochrome (Pfr) and CRS amplifies the action of phytochrome. The endogenous level of ascorbic acid levels enhanced by phytochrome was amplified by CRS. The lifetime of CRS was from 0 to 2 h and the peak of enhancement of ascorbic acid due to CRS was between 16 to 24 h of dark incubation after the end of the treatment. CRS was found to be ineffective on UV-B enhanced endogenous levels of ascorbic acid.Key words: ascorbic acid, cryptic red light signal, glycine max, phytochrome, ultraviolet-BThe phytochrome mediated morphogenesis involves the conversion of Pr [red absorbing form] to Pfr [far-red absorbing form] and the magnitude of the response is dependent on Pfr/P tot ratio established at the end of the irradiation.¹ In broom Sorghum anthocyanin synthesis induced by red light [R₁] is reversible with far-red light. But a second red pulse [R₂] given after the reversal resulted in increased anthocyanin production compared to the first pulse [R₁]. When the red pulse was repeatedly given after every reversal with far-red, the anthocyanin production increased proportionately to the number of previously given pulses.² Thus red pre-treatment induced a change in the cellular physiological state or change in content of a relevant substance[s] which is designated as Cryptic Red Light Signal [CRS] associated with red signal transduction.² CRS was first characterized in detail in Broom Sorghum as Pfr amplifying signal produced by red pre-irradiation. CRS is inactive in the absence of Pfr but enhances the action of Pfr. CRS escapes reversal when the plants are exposed to far-red and is probably produced by a different species of phytochrome, distinct from the conventional reversible phytochrome.³We have investigated whether CRS influences other phytochrome regulated processes in plants in addition to anthocyanin synthesis. We chose another process, the synthesis of endogenous ascorbic acid, which is also regulated by conventional phytochrome.⁴ In soybean, the endogenous level of ascorbic acid is enhanced by conventional far-red reversible form of phytochrome. In addition, an independent UV-B photoreceptor [non reversible with far-red light] also enhances the endogenous synthesis of ascorbic acid in soybean. By using repeated pulses of red light, we have demonstrated that the Cryptic Red Signal is operative in soybean also and it amplifies the red light induced enhancement in the level of ascorbic acid. That CRS is active only in the presence of Pfr is demonstrated by the fact that pre-irradiation with red light is ineffective in amplifying UV-B induced enhancement of ascorbic acid levels. A similar observation on UV-B induced anthocyanin synthesis has been made in Broom Sorghum.² A separate UV-B photoreceptor independent of phytochrome operates in the plants.⁵ Although CRS is presumably produced by pre-irradiation with red light, it does not enhance UV-B induced anthocyanin synthesis or ascorbic acid synthesis in the absence of formation of Pfr by the second red pulse.The life-time of CRS was determined as 6 h in 20°C and 3 h in 24°C grown seedlings of Broom Sorghum with reference to anthocyanin synthesis.² The life-time of CRS determined in soybean seedlings grown at 25°C was upto 1 h.⁶ Since growing seedlings at a low temperature enhanced the effectiveness of CRS in Broom Sorghum, it was concluded that low temperature may either extend the lifetime of CRS or generate higher amount of CRS.² Although the exact nature of CRS is yet to be analyzed, work in our laboratory has established the universal nature of this signal and evidences have been obtained for CRS effect in promoting red light induced hypocotyls inhibition in Cucumber seedlings and also red light induced synthesis of betacyanins in Amaranthus seedlings (submitted for publication).     

In Vivo Properties of Membrane-bound Phytochrome

After a 3-minute irradiation with red light, which saturates the phototransformation from the red light-absorbing form of phytochrome to the far red light absorbing form of phytochrome, about 40% of the phytochrome extractable from hooks of etiolated squash seedlings (Cucurbita pepo L. cv. Black Beauty) can be pelleted as Pfr at 17,000g after 30 minutes. Dark controls yield only 2 to 4% pelletable phytochrome in the form Pr. If a dark period intervenes between red irradiation and extraction, the bound Pfr gradually loses its photoreversibility. The time course for this destruction parallels the time course for phytochrome destruction in vivo following saturating red irradiation. The soluble fraction of phytochrome remains constant. These results suggest that in squash seedlings phytochrome destruction is related exclusively to the fraction which becomes membrane-bound. The induction of phytochrome binding by red light is not completely reversible by far red. In plants given saturating red followed immediately by saturating far red light, 12% of the phytochrome is found in the bound fraction as Pr if the phytochrome extraction is immediate. If a dark period intervenes between red-far red treatment and extraction, the bound phytochrome is released within 2 hours. A model of the binding properties of phytochrome, based on molecular interaction at the membrane is proposed, and possible consequences for the mechanism of action of phytochrome are discussed.     

Phytochrome Control of Longitudinal Growth and Phytochrome Synthesis in Maize Seedlings

The active, far-red light absorbing, form of phytochrome was found to inhibit growth and phytochrome levels in the mesocotyl and coleoptile of 4- to 5.5-day-old seedlings of Zea mays L. Short, low-irradiance red or far-red light treatments were used to produce different proportions of active phytochrome at the end of highdirradiance white-light periods, which left different levels of total phytochrome in the plants. After light treatments which left relatively high levels of spectrophotometrically assayable phytochrome in the seedlings, apparent phytochrome synthesis in the subsequent dark period was low regardless of the proportions of each form of the pigment present at the beginning of the dark period. In light treatments producing relatively low levels of assayable phytochrome, levels of apparent phytochrome synthesis in both red and far-red treatments and differences between apparent synthesis in red and far-red treatments were maximal. No simple correlation was found between growth and apparent phytochrome synthesis. However, growth and total phytochrome levels were positively correlated in both organs. Using a subtractive method of correlation, in which only phytochrome effects were plotted, strong linear relationships between phytochrome levels or longitudinal growth and P_fr levels were found in those light treatments leaving greater than 8% of dark control levels of phytochrome in the tissues. Using this technique non-linear, inverse relationships between P_fr and apparent phytochrome synthesis was found, indicating that modes of phytochrome control over phytochrome synthesis and growth differ. Our results are consistent with the view that in vivo assays of “bulk’ phytochrome reflect levels and states of the physiologically active phytochrome fraction under our experimental conditions in maize.     

The Effect of Red Irradiation on Plastid Ribosomal RNA Synthesis in Dark-grown Pea Seedlings

Dark-grown pea seedlings (Pisum sativum L.) were irradiated for a short period each day with low intensity red light (662 nm), red light immediately followed by far red light (730 nm), or far red light alone. Other plants were transferred to a white light regime (14 hours light/10 hours dark). There was no change in the amount of RNA in the tissue on a fresh weight basis after the various treatments. However, compared with dark-grown seedlings, those plants irradiated with red light showed an increase in the net RNA content per stem apex. In addition there was a two- to three-fold increase in ribosomal RNA of the etioplasts relative to the total ribosomal RNA. These increases were comparable to those found in plants grown in the white light regime. The changes were much smaller if the dark-grown plants were irradiated either with red light followed by far red light, or with far red light alone. Thus continuous light is not essential for the production of ribosomal RNA in plastids, and the levels of ribosomal RNA found in chloroplasts can also be attained in etioplasts of pea leaves in the dark provided the leaf phytochrome is maintained in its active form.     

Phytochrome-mediated accumulation of chloroplast DNA in pea leaves

Pea seedlings grown for 5 days in the dark were treated with red light for 5 min and grown for 2 more days in the dark. Effects of the red light on chloroplast DNA levels in the pea leaves were examined using probe DNA of the chloroplast-coded large subunit and nuclear-coded small subunit of ribulosebisphosphate carboxylase/oxygenase. The gene dosage of the large subunit, but not of the small subunit, was increased by red light. The increase was inhibited by subsequent far-red light treatment. These results indicate that accumulation of chloroplast DNA in the cell is mediated by phytochrome. Probably the replication of chloroplast DNA is mediated by phytochrome.     

De novo synthesis of phytochrome in pumpkin hooks

Phytochrome becomes density labeled in the hook of pumpkin (Cucurbita pepo L.) seedlings grown in the dark on D₂O, indicating that the protein moiety of the pigment is synthesized de novo during development. Red light causes a rapid decline of the total phytochrome level in the hook of etiolated seedlings but upon return to the dark, phytochrome again accumulates. These newly appearing molecules are also synthesized de novo. Newly synthesized phytochrome in both dark-grown and red-irradiated seedlings is in the red-absorbing form. Turnover of the red-absorbing form is indicated by the density labeling of phytochrome during a period when the total phytochrome level in the hook of dark-grown seedlings remains constant. However, it was not possible to determine whether this results from intracellular turnover or turnover of the whole cell population during hook growth.     

eid1: A New Arabidopsis Mutant Hypersensitive in Phytochrome A–Dependent High-Irradiance Responses

To identify specific mutants for components of phytochrome A (phyA) signaling in Arabidopsis, we established a light program consisting of multiple treatments with alternating red and far-red light. In wild-type seedlings, irradiation with multiple red light pulses can reduce the amount of phyA, which in turn decreases the high-irradiance responses (HIRs) mediated by the subsequent treatments with far-red light. Our mutants were able to avoid this red light–dependent reduction of the HIR. Here, we describe eid1, a new recessive mutant with increased sensitivity to far-red light. The eid1 mutation maps to the top of chromosome 4. The mutants showed no change in phenotype in darkness or under continuous white light, but they exhibited an increased sensitivity to red light and an increased persistence of HIR during prolonged dark phases after multiple short pulses of far-red light. The eid1 seedlings accumulated normal amounts of phytochrome and showed no alterations in the degradation or de novo synthesis of phyA. The expression of the Eid1 phenotype requires the presence of phyA. Our data provide evidence that EID1 is a negatively acting component in the phyA-dependent HIR-signaling pathway.     

Phytochrome control of amino acid synthesis in cotyledons of Sinapis alba

Continuous far red light, acting through phytochrome, stimulates the rate of incorporation of density label into amino acids in the cotyledons of Sinapis alba. It is shown that such stimulation leads to increased incorporation of label into proteins. This has important consequences for experiments in which rates of enzyme synthesis in light treated and dark grown plants are compared by labelling methods. The results of some such experiments are re-evaluated.     

The effect of phytochrome and white light of high and low intensity on the uptake and distribution of 14C-labelled kinetin in radish seedlings (Raphanus sativus)

The influence of light intensity and phytochrome on the uptake of ¹⁴C-kinetin (6-furfurylamino-[8- ¹⁴C]-purine) by the plant and the translocation of the phytochrome between the roots, the hypocotyl and the cotyledons were investigated with radish seedlings ( Raphanus sativus L. cv. Saxa Treib) grown in the dark or under white light of high (20,000 lux, 90 W m⁻²) or low intensity (2,000 lux, 14 W m⁻²). The highest uptake of labelled kinetin was found in plants grown in continuous darkness. The total uptake of kinetin was decreased by strong light and to a finally higher extent by weak light. Under white light most of the kinetin accumulated in the root, whereas in the dark an enhanced translocation of the phytohormone into the cotyledons was observed. In etiolated radish seedlings, light acting on phytochrome (daily 5 min red or far red light pulses) decreased the translocation of ¹⁴C-kinetin into the cotyledons. Under far red light a pronounced uptake of the phytohormone into the roots was found. The data are discussed with regard to the interaction of light and phytohormones on plant development.     

Spectrophotometric phytochrome measurements in light-grown Avena sativa L.

Phytochrome was studied spectrophotometrically in Avena sativa L. seedlings that had been grown for 6 d in continous white fluorescent light from lamps. Greening was prevented through the use of the herbicide San 9789. When placed in the light, phytochrome (P_tot) decreased with first order kinetics (_1/2 2 h) but reached a stable low level (2.5% of the dark level) after 36 h. This concentration of phytochrome remained constant in the light and during the initial hours of a subsequent dark period, but increased significantly after a prolonged dark period. Evidence suggests that the constant pool of phytochrome in the light is achieved through an equilibrium between synthesis of the red absorbing (P_r) and destruction of the far-red absorbing form (P_fr) of phytochrome. It is concluded that the phytochrome system in light-grown oat seedlings is qualitatively the same as that known from etiolated monocotyledonous seedlings, but different than that described for cauliflower florets.Abbreviations P_fr the far-red light absorbing form of phytochroma - P_r the red light absorbing form of phytochrome - P_tot P_r+P_fr - k_s rate constant of P_r synthesis - k_d rate constant of P_fr destruction - MOPS N-morpholino-3-propane-sulfonic acid - IRIS Tris (hydroxymethyl) amino methane - San 9789 4-chloro-5-(methyl amino)-2-(,,-trifluoro-m-tolyl)-3(2H)pyridazinone     

Comparative studies of the phytochrome system in cell cultures from different plants

Phytochrome contents have been assayed in vivo in cell suspension cultures of Petroselinum hortense, Daucus carota and Glycine max. After transferring the cells to fresh medium phytochrome increased in parallel with the increase in cell number, whereas the amount of phytochrome per cell remained constant. The rate of phytochrome reaccumulation after pretreatment with 15 h red light was very similar in all three systems (2.8–3.6 (e) 10^–5/h). Dark reversion and a fast and slow P_fr destruction were observed in all systems. The rate constants of these reactions varied strongly between the systems. The phytochrome systems of the cell cultures were compared with those of etiolated and light-grown seedlings and it was concluded that the cell suspension cultures of Petroselinum hortense and Daucus carota behaved similarly to light-grown seedlings. In contrast, those of Glycine max behaved similarly to a dark grown seedling.Abbreviations P_r'fr red, far-red absorbing forms of phytochrome - P_tot P_r+P_fr total amount of phytochrome - fwt fresh weight     

Light Rquirements for Photoperiodic Sensitivity in Cotyledons of Dark-grown Pharbitis nil

The light requirements for induction of flowering by a long dark period were investigated in dark-grown seedlings of Pharbitis nil Chois, cv. Violet. The cotyledons bcame photoperiodically sensitive to a 24 h dark period by two 1 min red irradiations (6.3 μmol m⁻² S⁻¹) separated by a 24 h dark period. The reversibility of the effect of brief red irradiations, and the effectiveness of low energies of red irradiation suggest the involvement of phytochrome in the induction of photoperiodic sensitivity. Partial de-etiolation occurred after these brief periods of red irradiation but the seedlings were not capable of net CO₂ uptakeeven 7 h after the start of the main light period that followed the critical dark period. A changing response to the duration of the priod of darkness given between the two short red irradiations showed the the correct phasing of an endogenous photoperiodic rhythm is needed for the attainment of photoperiodic snsitivity.     

Metabolic Adaptations of Plant Respiration to Nutritional Phosphate Deprivation

Shoots of the lazy-2 (lz-2) gravitropic mutant of tomato (Lycopersicon esculentum Mill.) have a normal gravitropic response when grown in the dark, but grow downward in response to gravity when grown in the light. Experiments were undertaken to investigate the nature of the light induction of the downward growth of lz-2 shoots. Red light was effective at causing downward growth of hypocotyls of lz-2 seedlings, whereas treatment with blue light did not alter the dark-grown (wild-type) gravity response. Downward growth of lz-2 seedlings is greatest 16 h after a 1-h red light irradiation, after which the seedlings begin to revert to the dark-grown phenotype. lz-2 seedlings irradiated with a far-red light pulse immediately after a red light pulse exhibited no downward growth. However, continuous red or far-red light both resulted in downward growth of lz-2 seedlings. Thus, the light induction of downward growth of lz-2 appears to involve the photoreceptor phytochrome. Fluence-response experiments indicate that the induction of downward growth of lz-2 by red light is a low-fluence phytochrome response, with a possible high-irradiance response component.     

In vivo phytochrome reversion in immature tissue of the alaska pea seedling

Reversion of far red-absorbing phytochrome to red-absorbing phytochrome without phytochrome destruction (that is, without loss of absorbancy and photoreversibility) occurs in the following tissues of etiolated Alaska pea seedlings (Pisum sativum L.): young radicles (24 hours after start of imbibition), young epicotyls (48 hours after start of imbibition), and the juvenile region of the epicotyl immediately subjacent to the plumule in older epicotyls. Reversion occurs rapidly in the dark during the first 30 minutes following initial phototransformation of red-absorbing phytochrome to far red-absorbing phytochrome. If these tissues are illuminated continuously with red light for 30 minutes, the total amount of phytochrome remains unchanged. Beyond 30 minutes after a single phototransformation or after the start of continuous red irradiation, phytochrome destruction commences. In young radicles, sodium azide inhibits this destruction, but does not affect reversion. In older tissues in which far red-absorbing phytochrome destruction begins immediately upon phototransformation, strong evidence for simultaneous far red-absorbing phytochrome reversion is obtained from comparison of far red-absorbing phytochrome loss in the dark following a single phototransformation with far red-absorbing phytochrome loss under continuous red light.     

The involvement of phytochrome in controlling chlorophyll and 5-aminolevulinate formation in a gymnosperm seedling (Pinus sylvestris)

Chlorophyll a (Chl a) accumulation in the cotyledons of Scots pine seedlings (Pinus sylvestris L.) is much higher in the light than in darkness where it ceases 6 days after germination. When these darkgrown seedlings are treated with continuous white light (3,500 lx) a 3 h lag phase appears before Chl a accumulation is resumed. The lag phase can be eliminated by pretreating the seedlings with 7 h of weak red light (0.14 Wm^-2) or with 14 red light pulses separated by relatively short dark periods (<100 min). The effect of 15s red light pulses can be fully reversed by 1 min far-red light pulses. This reversibility is lost within 2 min. In addition, the amount of Chl a formed within 27 h of continuous red light is considerably reduced by the simultaneous application of far-red (RG 9) light. It is concluded that phytochrome (P_fr) is required not only for the elimination of the lagphase but also to maintain a high rate of Chl a accumulation in continuous light. Since accumulation of 5-aminolevulinate (ALA) responds in the same manner as Chl a accumulation to a red light pretreatment it is further concluded that ALA formation is the point where phytochrome regulates Chl biosynthesis in continuous light. No correlation has been found between ALA and Chl a formation in darkness. This indicates that in a darkgrown pine seedling ALA formation is not rate limiting for Chl a accumulation.Abbreviations Chl chlorophyll(ide) - PChl protochlorophyll(ide) - ALA 5-aminolevulinate - P_r the red absorbing form of phytochrome - P_fr the far-red absorbing form of phytochrome - P_tot total phytochrome ([P_r]+[P_fr])