PHOTOREVERSIBLE PROTON DISSOCIATION AND ASSOCIATION IN PEA PHYTOCHROME AND ITS CHROMOPEPTIDES

Abstract— Effect of red-light irradiation on the medium pH at 10d?C was measured and compared among unbuffered solutions of the 121-kDa native pea (Pisum sativum cv. Alaska) phytochrome and its 114- and 62-kDa fragments in a red-light-absorbing form (P_r), all of which converted to far-red-light-absorbing form (Pf_r) on red-light irradiation. Red-light irradiation induced alkalinization in the solutions of the phytochrome and the fragments in the pH range 6.6-7.2 and 6.2-7.8, respectively. The amount of protons taken up by the 121-kDa phytochrome was less than one half of that of the 114-kDa fragment. Red-light irradiation induced acidification in the solutions of the 114- and the 62-kDa fragments above pH 7.8. In the solutions of the 121-kDa phytochrome, however, the irradiation induced no pH change at pH 7.2-8.2, and only a slight acidification at pH 8.2-8.7, which may be ascribed to a small amount of contamination from the 114-kDa fragment. All these red-light-induced pH changes were reversible following exposure to far-red light. The 7-kDa polypeptide(s) of the native 121-kDa phytochrome, which is lacking in the 114-kDa fragment, thus, prohibited proton transfer between phytochrome and the medium. A red-light-induced pH change was also measured in unbuffered solutions of the 39-kDa fragment of the phytochrome and of the 114-kDa fragment in the presence of 0.8 mM soyasaponin I. The 39-kDa fragment showed partially photoreversible conversion between a spectral form having an absorption maximum at 659 nm (P₆₅₉) and a bleached form, P_***. The 114-kDa fragment in the presence of the saponin showed a photoreversible conversion between P65V and Pb,. Exposure of P₆₅₉ from the 39-kDa fragment and from the 114-kDa fragment in the presence of the saponin to red light, caused acidification of the medium in the pH range 6.8-8.8 and 7.2-9.0, respectively, but no change at pH 6.2-6.8 and 6.4-7.2, respectively. The acidification of the latter was reversible following a far-red-light irradiation, but that of the former was only partially photoreversible. Proton uptake of phytochrome was inhibited by tryptic degradation to the 39-kDa fragment and also by the presence of the saponin. Only proton release was observed during the photoconversion from P₆₅₉ and P_***hl. It is suggested that a phytochrome molecule has possible site(s) for both proton release and for uptake and that the proton release reaction may be correlated to the photoconversion process(es) prior to the bleached intermediate (I_***) of phytochrome.     

PHYTOCHROME CONTROL OF ITS OWN SYNTHESIS IN Sorghum vulgare AND Avena sativa

The accumulation of phytochrome in the dark was measured for Avena sativa seedlings after a white light pretreatment and for Sorghum vulgare seedlings after continuous red or far-red light treatments, using the herbicide Norflurazon to prevent greening under continuous irradiation. In both cases the accumulation of phytochrome depends on the state of the phytochrome at the light-dark transition: high P_fr levels (red light pulse) led to a slower rate of phytochrome accumulation than lower P_fr levels (long wavelength far-red (RG 9) light pulse). Poly-(A⁺)-RNA was isolated fromA. sativa seedlings grown for 48 h in darkness + 24 h WL + light pulse (5 min) (red, RG 9 light, red followed by RG 9 light or RG 9 followed by red light pulse) + 19 h darkness. The poly-(A⁺)-RNA was translated in a rabbit reticulocyte lysate system and the translation products were immunoprecipitated by specific anti-phytochrome antibodies. It was demonstrated that the activity of mRNA coding for phytochrome was under phytochrome control.     

MULTIPLE CHROMOPHORE SPECIES IN PHYTOCHROME*,†,‡

Abstract— Buffered aqueous solutions of pure phytochrome, when irradiated at 730 nm, had a main absorption band at about 660 nm and a shoulder or secondary band at 580–600 nm. When irradiated at 660 nm, these absorption bands bleached and a pair of bands at 670 and 725–730 nm appeared. When 660 nm irradiated samples were placed in the dark the 730 nm absorption slowly bleached and the 670 nm absorption band shifted to 660 nm. The kinetics of the bleaching indicated that two populations of P_FR existed initially. These two populations decayed by first order kinetics with k's of 4.8 × 10^-4 sec^-1 and 3.1 × 10^--⁵ sec^-1at 25°. While the bleaching of P_FR was occumng, the appearance of the 660 nm and 580–600 nm absorption bands characteristic of P_R took place. The kinetics of the increase in the 580 and 660 nm absorption bands indicated that it was arising from two populations of reactants by two first order reactions with k's of 6.4 × 10^-4 sec^-1 and 3.1 × 10^-5sec^-1 at 25°. When the sodium chloride concentration of the solvent was changed the proportions of the kinetically different populations were altered. In some conditions, especially in the presence of air. reversible but non-reciprocal changes in the four absorption bands were observed. These effects were evident after the lapse of many hours in the dark. When native phytochrome was treated with sodium dodecyl sulfate all absorption bands but the 580–600 nm absorption band were bleached and photoreversibility was lost. When native phytochrome was treated with glutaraldehyde, the 730 nm absorption band was bleached but photoreversibility was retained. It was concluded that at least four species of chromophore exist in phytochrome with absorption maxima at 580, 660 , 670 and 730 nm. Each chromophore is capable of being bleached by appropriate irradiation or in the dark by chemical reactions rather than photochemical reactions. The reactions are probably coupled redox reactions between the 580–660 nm pair and the 670–730 pair of chromophores. Discrepancies observed in the reciprocity of the absorption changes in these paired bands are probably due to various degrees of uncoupling and secondarily to the redox potential of the solvent when such uncoupling occurs.     

CONTROL BY PHYTOCHROME OF CHLOROPHYLL SYNTHESIS IN SEEDLINGS OF SORGHUM VULGARE

The strong effect of light pretreatments on the synthesis of chlorophyll-a and-b in the shoot of Sorghum vulgare (kept under saturating white light) can be attributed to phytochrome only. No specific blue light effect was found. The phytochrome system appears to function perfectly normally under these conditions. Escape from reversibility is not detectable up to approximately 40 min after the onset of an inductive red light pulse. Thereafter, escape is fast, being completed at approximately 2.5 h after the inductive light pulse.     

PREVENTION BY PHYTOCHROME OF PHOTODELAY IN CHLOROPHYLL ACCUMULATION

A photodelay in chlorophyll- a and -b accumulation is observed in mustard ( Sinapis alba L.) cotyledons during the first 3 h after the onset of white light even at medium light fluxes (3500 lx). A pretreatment of two red light pulses or a 12 h far-red light pretreatment, both operating through phytochrome. prevent the photodelay completely. This is a specific phytochrome effect since'it can be separated from the effects of phytochrome on the rates during pre-steady state and steady state phases of chlorophyll accumulation in saturating white light. Thus, photostability of chlorophyll in nature is a photoresponse mediated through phytochrome.     

IS PHYTOCHROME INVOLVED IN THE LIGHT-MEDIATED CAROTENOGENESIS IN FUSARIUM AQUAEDUCTUUM AND NEUROSPORA CRASSA?*

Abstract— In the two fungal species ( Fusarium and Neurospora ) carotenogenesis has been described as a blue light effect. Generally, phytochrome was believed to be absent in fungi. Recently, work was reported suggesting that this might not strictly be the case. Therefore, we very thoroughly tested these two organisms for any red light effect on carotenogenesis. No action of phytochrome was found, either as a 'low irradiance response' or a 'high irradiance response'. Also, no sequential interaction between blue and red light and between UV and red light was observed. Therefore, we conclude that phytochrome is not involved in carotenogenesis in Fusarium and Neurospora.     

PHOTOREVERSIBLE CHANGES IN pH OF PEA PHYTOCHROME SOLUTIONS

Abstract— Photoinduced pH changes in unbuffered solutions of undegraded pea phytochrome were studied at 10_oC by using a glass electrode. Red light irradiation caused alkalinization of the solutions in the pH range 5.2–xs7.5 and acidification in pH 7.5–8.9. The pH changes were fully reversed by a subsequent irradiation with far-red light. The red and far-red light effects were repeatedly reversible. The solution of tryptic peptide of phytochrome (mol. wt 60000) showed similar photoreversible pH changes.     

THE EFFECT OF PROLONGED LIGHT EXPOSURE ON THE EFFECTIVENESS OF PHYTOCHROME IN ANTHOCYANIN SYNTHESIS IN TOMATO SEEDLINGS*

Abstract— The hypocotyl of the tomato ( Lycopersicon esculentum ) seedling synthesizes large amounts of anthocyanin if exposed to prolonged light. Single light pulses are totally ineffective. The involvement of phytochrome can be shown by light pulse treatments following a prolonged light exposure. It is predominantly the action of blue/UV light which leads to a high responsiveness of anthocyanin synthesis towards phytochrome. Moreover, the data suggest a phytochrome-independent action of blue/UV light, in particular of UV-B, on anthocyanin synthesis.     

EFFECT OF PHYTOCHROME ON THE BIOSYNTHESIS OF ACYCLIC AND CYCLIC CAROTENOIDS IN HIGHER PLANTS

Radish plants were grown in the presence of three different herbicides that interfere with the formation of the normal range of cyclic carotenoids, leading to an accumulation of acyclic biosynthetic intermediates, mainly phytoene (SAN 6706 and amitrole) and zeta-carotene (3852). Plants were then irradiated by four different light programs in order to gain more insight into the first steps of carotenoid biosynthesis and their control by light and phytochrome. In all cases, herbicide-treated and control, carotenoid biosynthesis was greatly enhanced by red light consistent with an effect of phytochrome on the early steps of the pathway. However, similar enhancement was also obtained after treatment with far-red light. Indeed with SAN 6706-treated plants synthesis of phytoene was stimulated to a much greater extent by far-red light given alone, than by red light. The involvement of phytochrome in the regulation of carotenoid biosynthesis appears not to be as simple as previously supposed.     

CHANGES IN THE RATES OF PHOTOCONVERSION OF PHYTOCHROME DURING ETIOLATION IN MUSTARD SEEDLINGS

Abstract— The relative phytochrome photoconversion rates in cotyledons and hypocotylar hook of etiolating mustard ( Sinapis alba L.) seedlings were measured between 16 and 96 h after sowing. It was found that at constant fluence rates photoconversion rate in red light increases in both organs with time whereas the photoconversion rate in far-red (756 nm) light decreases with time of development. Since the isosbestic point remains constant, it was concluded that the observed changes cannot be attributed to changes of extinction coefficients. It was not possible, however, to decide whether the observed changes are due to changes of light attenuation or quantum yields.     

APPARENT INCREASE IN PHOTODETECTABLE PHYTOCHROME IN THE PRESENCE OF CALCIUM CARBONATE*

Abstract— –Using squash seedling extracts ( Cucurbita pepo L.), we describe an apparent increase in photodetectable phytochrome content that is depended upon the use of either CaCO₃ or starch as a scattering agent and is also a function of preirradiation with red light of either intact tissue or crude extracts prior to sample preparation for spectrophotometric assay. This apparent increase in photodetectable phytochrome content requires about 1 h for full expression after addition of the scattering agent. If irradiations are given in vitro , the increase is partially reversed by far red light when using squash extracts, and is fully reversed with Aoena and Zea extracts. For squash extracts the magnitude of this increase. which is typically between 20 and 40%. is quantitatively correlated with both the amount of Pfr produced by a brief red irradiation and with the proportion of the total phytochrome pool that is pelletable upon centrifugation at 20,000 g . The correlation with pelletable phytochrome does not hold for Auena and Zea , at least when irradiations are gwen in uitro . The increase in photodetectable phytochrome may result from changed phytochrome extinction, changed phototransformation quantum yields, and/or specific trapping of phytochrome by the scattering agent as it settles. An important consequence of these data is that they indicate a need for caution when using a scattering agent during spectrophotometric assay of phytochrome.     

THE MODE OF INTERACTION BETWEEN BLUE (UV) LIGHT PHOTORECEPTOR AND PHYTOCHROME IN ANTHOCYANIN FORMATION OF THE SORGHUM SEEDLING

Two non-photosynthetic photoreceptors (phytochrome and a blue light photoreceptor) are involved in light-mediated anthocyanin synthesis in the mesocotyl of Sorghum seedlings. The present study was undertaken to investigate the kind of interaction between phytochrome and the blue light photoreceptor. The data show that phytochrome (P_fr) can only act once a blue light effect has occurred. On the other hand, the blue light effect cannot express itself without P_fr. It is concluded that there is an obligatory dependency (or sequential interaction) between the blue light effect and the light effect occurring through phytochrome, although the blue light photoreaction per se is not affected by the presence or absence of phytochrome. The latter statement is based on the results of dichromatic experiments, i.e. simultaneous, high fluence rate irradiation with two kinds of light. Blue light can be replaced by UV light. It is not clarified yet whether the effect of blue and UV light is due to the same photoreceptor.     

IDENTIFICATION OF TRYPTIC CHROMOPEPTIDES OF PHYTOCHROME ON SODIUM DODECYL SULFATE GELS: IMPLICATIONS FOR STRUCTURE

Abstract— After electrophoresis on sodium dodecyl sulfate polyacrylamide gels, bleached chromopeptides of phytochrome can have their blue color restored by soaking the gels in 20% trichloroacetic acid. The blue bands have a broad absorption maximum between 630 and 655 nm, characteristic of denatured phytochrome. The restored color retains most of its intensity for up to 2 h, but gradually bleaches again until it disappears completely within 24 h. This visualization method is used to identify the number and sizes of phytochrome chromopeptides produced by limited tryptic digestion. The results reveal some structural requirements for photoreversibility and are consistent with a model of phytochrome structure that predicts a high degree of symmetry within the native subunit.     

THE CONTROL BY PHYTOCHROME OF NITRATE REDUCTASE IN THE CURD OF LIGHT-GROWN CAULIFLOWER

Abstract— The activity of nitrate reductase from the curd of light-grown cauliflower ( Brassica oleracea (L) var botrytis (DC) 'St. Hilary') is modulated by nitrate and by light. Using broad-band sources of equal photosynthetically active radiation but with different proportions of red and far-red light, a linear relationship between nitrate reductase activity and ψ(Estimated phytochrome photoequilibrium) was obtained. This relationship, apparent after 8 h incubation, was maintained and little altered after 48 h incubation. The linearity was apparent between ψE 0.26 and ψE 0.69; ψE 0.26 being no more effective than a dark control. Far-red reversibility confirmed the involvement of phytochrome. Brief pulses of red light were also used to establish a range of phytochrome photoequilibria within the tissue. Again a linear relationship between ψ and nitrate reductase activity was obtained with a threshold for the response at ψ 0.3. With both monochromatic and broad-band sources it was seen that neither photon fluence rate nor duration of exposure affected the final activity of the enzyme and that phytochrome was acting solely through ψ (or [Pfr] since phytochrome is stable in this tissue) to bring about these responses.     

PHYTOCHROME IN ETIOPLASTS IN RELATION TO CHLOROPHYLL ACCUMULATION*

Abstract— De-etiolation of maize seedlings reduces their sensitivity for red light potentiation of rapid chlorophyll accumulation in white light. An earlier proposal (Raven and Spruit, 1973) attributes this to migration of the far-red absorbing form of phytochrome (P_fr) to receptors essential for chlorophyll synthesis, thereby increasing the local P_fr/total phytochrome (P_tot)ratio. We have studied etioplasts as possible loci for such P_(r receptors. The level of spectrophotometric phytochrome in purified etioplasts isolated from red preirradiated maize seedlings was higher than that of dark grown plants. The difference was marginally significant, however. We argue that migration of a fraction of cytoplasmic P_fr to the etioplasts, too small to be spectrophotometically demonstrable, could still meet the requirements of the model. Dark destruction of bulk spectrophotometric P_fr following saturating red irradiation of seedlings is not paralleled by a decrease of etioplast phytochrome. the latter remaining essentially constant over long periods. On the other hand, the potentiating effect of red light in intact seedlings is still partially reversible by far red light even after 24 h of darkness when destruction of bulk P_fr is complete. Since this demonstrates persistent presence of P_fr active in potentiation, we propose that at least part of this P_fr is associated with the etioplasts.     

PHOTOCONTROL OF ANTHOCYANIN SYNTHESIS IN TOMATO SEEDLINGS: A GENETIC APPROACH*

The photocontrol of anthocyanin synthesis in dark-grown seedlings of tomato (Lycopersicon esculentum Mill.) has been studied in an aurea (au) mutant which is deficient in the labile type of phytochrome, a high pigment (hp) mutant which has the wild-type level of phytochrome and the double mutant au/hp , as well as the wild type. The hp mutant demonstrates phytochrome control of anthocyanin synthesis in response to a single red light (RL) pulse, whereas there is no measurable response in the wild type and au mutant. After pretreatment with 12 h blue light (BL) the phytochrome regulation of anthocyanin synthesis is 10-fold higher in the hp mutant than in the wild type, whilst no anthocyanin is detectable in the au mutant, thus suggesting that it is the labile pool of phytochrome which regulates anthocyanin synthesis. The au/hp double mutant exhibits a small (3% of that in the hp mutant) RL/far-red light (FR)-reversible regulation of anthocyanin synthesis following a BL pretreatment. It is proposed that the hp mutant is hypersensitive to the FR-absorbing form of phytochrome (P_fr) and that this (hypersensitivity) establishes response to the low level of P_fl. (below detection limits in phytochrome assays) in the au/hp double mutant.     

THE FUNCTION OF PHYTOCHROME IN THE NATURAL ENVIRONMENT—IV. LIGHT QUALITY AND PLANT DEVELOPMENT

Abstract— Studies of the effect of light quality on the growth of Cucurbita pepo L . and Chenopodium album L . showed that large changes in morphological development can be induced by altering the proportion of red and far-red in the incident radiation. Although phytochrome photoequilibria established at the beginning of the dark period affected development, similar changes were achieved with long term and continuous irradiation. The change in the growth pattern of C. album (a common weed species in cultivated land) caused by simulated wheat canopy shade, appeared to involve a redirection of growth towards processes which would achieve greater height at the expense of lateral growth. The evidence presented supports the hypothesis that phytochrome may be involved in the detection of mutual shading and the modification of development in an appropriate manner.     

IDENTITY OF THE PHOTORECEPTORS FOR THE PERCEPTION OF IRRADIANCE IN PHOTOSYNTHETIC LIGHT ACCLIMATION IN TOMATO*

The photoreceptors involved in the photosynthetic acclimation of tomato (Lycopersicon esculentum Mill.) to increased irradiance were investigated. Plants were transferred from 100 p.mol m^?2 s^?1 cool white fluorescent light to higher irradiances of white light or white light supplemented with blue, red, green or yellow light. In these experiements light of all wavelengths tested was capable of causing acclimation as measured by the rate of light-saturated photosynthesis. It was concluded that the photosynthetic system rather than the blue-absorbing photoreceptor or phytochrome system acts as the photoreceptor for increased irradiance. No acclimation was observed in response to increased CO₂ levels, but increasing light integral at a constant irradiance was effective in bringing about acclimation. We conclude that acclimation is a response to increased photosynthetic light capture rather than increased photosynthetic carbon fixation, and involves a photon counting mechanism.     

A NOVEL EFFECT OF UV-B IN A HIGHER PLANT (SORGHUM VULGARE)

Abstract— Two non-photosynthetic photoreceptors (phytochrome and the usual blue/UV light photoreceptor) were previously found to be involved in light-mediated anthocyanin synthesis in the mesocotyl of Sorghum seedlings (Drumm and Mohr, 1978). The decisive point is that phytochrome can act only after a blue/UV light effect has occurred. On the other hand, the expression of the blue/UV light effect is controlled by phytochrome ('obligatory sequential action'). A strong positive interaction between the blue/UV-A and the UV-B part of the spectrum was found, in addition to the above sequential action: an inductive effect of blue or UV-A light can only express itself fully if short wavelength UV (approximately 300–320nm. UV-B range) is also given, either after the blue/UV-A light or simultaneously. Since even small amounts of the UV-B are strongly effective it is probable that this effect plays a role under natural conditions and may not be considered as a mere laboratory artifact.     

PHOTOCONTROL OF PHYTOCHROME DESTRUCTION AND BINDING IN DICOTYLEDONOUS vs MONOCOTYLE-DONOUS SEEDLINGS. THE INFLUENCE OF WAVELENGTH AND IRRADIANCE

Abstract— The irradiance and wavelength dependence of phytochrome destruction in vivo was analysed in etiolated cotyledons of Cucurbita pepo L. and etiolated seedlings of Amaranthus caudatus L. In contrast to grass seedlings, the rate of P _tot destruction could only be saturated by light sources that establish relatively high P _fr levels (about 50% of total phytochrome, corresponding to the photostationary state established by 693 nm light). To explain the irradiance dependence of P _tot destruction in dicots at irradiances above 0.1 Wm^-2, where the light reaction is at least one order of magnitude faster than P _fr destruction, we suggest there is a fast intercalary dark reaction between photoreaction and destruction. This dark reaction is probably—as in grass seedlings—the binding of P _fr to a receptor site. We conclude that the differences between dicots and grass seedlings with respect to the phytochrome system are of a quantitative rather than a qualitative nature.