THE FUNCTION OF PHYTOCHROME IN THE NATURAL ENVIRONMENT—I. CHARACTERIZATION OF DAYLIGHT FOR STUDIES IN PHOTOMORPHOGENESIS AND PHOTOPERIODISM

Abstract— The daily changes in spectral energy distribution of natural daylight, with special reference to the red and far-red wayelength bands, are outlined. The effects of solar elevation and sky condition are described. The changes in the proportions of red and far-red radiation in daylight which occur at sunrise and sunset are discussed in relation to the possible function of phytochrome in photoperiodic timing.     

THE FUNCTION OF PHYTOCHROME IN THE NATURAL ENVIRONMENT—III. MEASUREMENT AND CALCULATION OF PHYTOCHROME PHOTOEQUILIBRIA

Abstract— Phytochrome photoequilibria have been measured in dark-grown Phaseolus uulgaris L . and Cucurbita pepo I . hypocotyl hooks which had been exposed to various natural and artificial radiation sources. Mean phytochrome photoequilibria ( φ ) varied from 0.20 within a wheat canopy to 0.54 above, although lower values were occasionally observed in densely shaded areas. Greater variation in phyto chrome photoequilibria and lower levels of P_fr were recorded within a sugar beet canopy. The range of photoequilibria was φ= 0.04 in dense shade to φ= 0.54 above the canopy. Photoequilibrium was achieved within 5 s in mid-day sunlight and approximately 30 s in dense canopy shade.
A close correlation was found between φ and the ratio of the quantum flux in the red and far-red wavelength bands (ζ) in broad spectrum (400–800 nm) radiation. This relationship allows direct prediction of φ from a knowledge of ζ. Phytochrome showed greatest sensitivity to spectral changes in the range ζ= zero to ζ= 1.0, which is the range found in the natural environment.
The observations provide support for the hypothesis that phytochrome is involved in the detection of shading by plants.     

ANTAGONISTIC EFFECTS OF RED AND FAR-RED LIGHTS ON THE STABILITY OF PHOTOSYSTEM II IN PEA LEAVES EXPOSED TO HEAT

Abstract— The presence of light during exposure of intact pea leaves to high temperature (40°C) protects Photosystem II (PSII) against inactivation, as indicated by the preservation of the maximal variable 685 nm chlorophyll fluorescence and the photosynthetic oxygen evolution. This photoprotection was observed (i) to be saturated at low fluence rates ( ca 10 W m^-2) and (ii) to be strongly dependent on the spectral characteristics of the light. It was specifically induced by red light (630–670 nm) whereas other wavelengths were much less protective. A strong antagonism between red and far-red lights was also observed, with PSII stabilization by red light being partially cancelled by additional far-red light.     

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.     

PHYTOCHROME-MEDIATED PHOTOTROPISM AND DIFFERENT DICHROIC ORIENTATION OF Pr AND Pfr IN PROTONEMATA OF THE FERN ADIANTUM CAPILLUS-VENERIS L.

Abstract— Single-celled protonemata of Adiantum capillus-veneris were cultured under continuous red light for 6 days and then in the dark for 15 h. Brief local exposure of a flank (5 times 20 /mi) of the subapical region of a protonema to a microbeam of red light effectively induced a phototropic response toward the irradiated side. The degree of the response was dependent upon the fluence of the red light. Red/far-red reversibility was typically observed in this photoreaction, showing that phytochrome was the photo-receptive pigment. When the flank was irradiated with a microbeam of linearly polarized red and far-red light, red light with an electrical vector parallel to the cell surface was most effective. However, the far-red light effect was most prominent when its electrical vector was normal to the cell surface. These polarized light effects indicate the different dichroic orientation of P_r (red-light-absorbing form of phytochrome) and P_r (far-red-light-absorbing form of phytochrome) at the cell flank.     

SPECTRAL CHARACTERIZATION OF HIGH-MOLECULAR-WEIGHT PHYTOCHROME*

Abstract— Previous information about the spectral and photochemical properties of phytochrome in vitro has apparently been determined in large part with chromopeptides derived from the native molecule by proteolysis. Characterization of high-mol-wt phytochrome in vitro has led to the observation that the far-red-absorbing form (Pfr) may undergo relatively large and reversible changes in far-red extinction. Phytochrome preparations which exhibit reduced far-red extinction as Pfr also exhibit a rapid reappearance of red absorbance after discontinuing the red illumination used to establish photostationary equilibrium. This rapid change in the red spectral region is not accompanied by any equivalent absorbance change in the far-red. The molecular basis for these newly reported spectral properties is not known. However, both properties may be eliminated by the addition of either 2-mercaptoethanol or ethylenediaminetetraacetic acid.     

PHYTOCHROME-MEDIATED PHOTOTROPISM IN PROTONEMATA OF THE MOSS Ceratodon purpureus BRID

Abstract— Protonemata of the moss Ceratodon purpureus cultured in white light were transferred to darkness for 3 days and then used for phototropic experiments. Irradiation of the apical region of vertically position protonemata with small beams (0.2 mm) of red light induced a growth response towards the irradiated side (positive phototropism). The phototropic response showed irradiance dependence. The effect of red light was completely reversed by far-red light following red light irradiations, demonstrating that phytochrome was the photoreceptor pigment. Far-red light or UV-blue light had no influence on either bulging or phototropism. Experiments with linearly polarized red or far-red light showed a different dichroic distribution of phytochrome in its different forms, the red-absorbing form, P_r and the far-red-absorbing form, P_fr. Red light with a vibration plane parallel to the long axis of the filaments was most effective. The effectiveness of far-red light was expressed best when its vibration plane was 90° to the electrical vector of the inductive red light.     

THE PHOTORECEPTORS INVOLVED IN ANTHOCYANIN SYNTHESIS

Abstract— Experiments with irradiation sequences where red precedes far-red lead to the conclusion that, in turnip, phytochrome is the only pigment mediating anthocyanin synthesis in red and far-red. Results from experiments where far-red precedes red, however, suggest that more than one reaction is involved. A possible interpretation is that the 'high-energy' reaction in far-red and the low energy red/far-red reversible reaction are mediated by two different forms of phytochrome.
The 'high-energy' reaction in blue light does not appear to depend on phytochrome.     

GENETIC AND PHYSIOLOGICAL STUDIES OF THE EFFECT OF LIGHT ON THE DEVELOPMENT OF THE MOSS, PHYSCOMITRELLA PATENS

The germination of Physcomitrella patens spores only occurs when wet spores are exposed to light. Depending on their ripeness, spores require from 44 to 64 h illumination to bring about maximum germination. There is a lag period of about 15 h between the reception of sufficient light to elicit germination before germination can be observed. Wavelengths in the range 640–64080 nm are much more effective in inducing germination than longer or shorter wavelengths, but far-red reversal of red light induction of germination has not been demonstrated. Light also has very marked effects on protonemal and gametophore development. In darkness, only caulonemata are produced, and these grow negatively geotropically. No new gametophores develop but existing gametophores grow negatively geotropically, etiolate and bear only scale leaves. In light, chloronemata, as well as caulonemata are produced, the former grow positively phototropically, while the latter grow at right angles to the direction of light, and neither cell type is sensitive to gravity. In the light, gametophores grow positively phototropically, are indifferent to gravity, produce large leaves and do not etiolate. All these responses to light by protonemata and gametophores are shown by cultures growing in a 23 h dark/l h red light cycle, but if this red light treatment is followed by 15min far-red light, the effect of the red light is reversed, indicating an involvement of phytochrome in the mediation of these responses. Mutants showing abnormal growth in the dark have been isolated, as well as mutants having abnormal phototropic responses. The latter type has lost the phototropic response of both the protonemal cell types, as well as of gametophores, indicating that these different responses may share a common component.     

THE ROLE OF CYTOKININS IN THE PHYTOCHROME-MEDIATED GERMINATION OF DORMANT IMBIBED CELERY (APIUM GRAVEOLENS) SEEDS

The dormancy of celery seeds was broken by red light treatment given during imbibition and this effect was reversed by far-red light. The exact quantitative relationship between the timing and duration of red light treatment and dormancy-break has not been elucidated. However, the accumulated effect of daily 5 min exposures was greater than a single 5 min exposure on the second day of imbibition. The effects of red light treatment were simulated by treatment with a mixture of the gibberellins A₄ and A₇ and N⁶-^-benzyladenine. A correlation between the requirement for red light and the requirement for exogenous cytokinins in the presence of GA_4/7 was demonstrated by using six cultivars with different dormancy characteristics. In order to investigate the role of natural cytokinins in dormancy-break, quantitative and qualitative changes in cytokinins were measured in celery seeds immediately after red-light treatments. Rapid increases in n-butanol-soluble cytokinins following irradiation were associated with concomitant decreases in water-soluble cytokinins, suggesting a red light induced cytokinin conversion. Three of the cytokinins present in the n-butanol fraction of celery seed extracts were chromatographically similar to zeatin, zeatin riboside and N⁶-^-A²-^-isopentenyladenosine (i⁶Ado). The elution profiles from a PVP column of two others were similar to BA and its riboside. The possibility that these two cytokinins act as specific dormancy-breaking cytokinins in celery seeds is discussed. There was little evidence of reversal of the cytokinin conversion mechanism by far-red light exposure.     

LIGHT REQUIREMENTS FOR THE ENHANCED SYNTHESIS OF A PLASTID mRNA DURING SPIRODELA GREENING

A plastid mRNA (5 × 10⁵ mol wt) appears as a burst 3 h after white light greening of steady state dark grown plants of Spirodela oligorrhiza. In this species, chlorophyll synthesis begins after 12 h. The light requirement is different from the pulse of far-red reversible red light required to abolish the lag of chlorophyll synthesis in many species, including Spirodela. Continuous high energy far-red is not stimulatory. When the illumination is not continued throughout the time of incorporation, the stimulation is minimal. Low energy blue and red light are stimulatory, and green and far-red light are ineffectual. Blue light was > 5 times as effective as red light at many dose levels. Illumination with 3 × 10¹⁷ quanta/m²/s (50pEm/cm²/s) blue light at 476 nm gave about half maximum stimulation.     

STIMULATION OF THE SHIBATA SHIFT BY PHOTOCHROME IN THE COTYLEDONS OF THE MUSTARD SEEDLING SINAPIS ALBA L.

Abstract— In the cotyledons of the mustard seedling Sinapis alba L. the duration of the Shibata shift can be greatly shortened by a pretreatment with light pulses prior to the protochlorophyllide– chloro-phyllide a photoconversion. It was shown that the light pulses act through photochrome (P _fr ). Since reversibility of a red light pulse induction by a far-red light pulse is rapidly lost (within 2 min) it is concluded that at least the initial action of P_fr occurs rapidly in this response. On the other hand, the effect of a red light pulse on the rate of protochlorophyll regeneration in the mustard seedling cotyledons is fully reversible by a far-red light pulse for more than 5 min. It is concluded that control of protochlorophyll regeneration and control of the Shibata shift by phytochrome cannot be consequences of the same initial action of P_fr Apparently P_fr controls both phenomena independently.     

ACTION SPECTRUM FOR PHOTOREVERSION OF THE ACTIVE Pfr-FRACTION OF Mougeotia in vivo

Abstract— The dichroic oriented fraction of the far-red light absorbing form of phytochrome (Pfr) in the green alga Mougeotia was characterized by action spectroscopy. Microbeam irradiations had to be used for the induction of chloroplast movement in Pfr-containing cells, because of the special dichroic absorption characteristics of the red light absorbing form of phytochrome (Pr) and Pfr in the alga. Fluence-response curves were elaborated especially in the far-red spectral region by reverting Pfr to Pr at the flanks of the cells and thus generating Pfr-gradients. Linearly polarized light vibrating perpendicularly to the cell axis was used, thus corresponding to the S,-transition moments of Pfr at the flanks of the cells. The action spectrum is characterized by a peak at approximately 715 nm and a very pronounced decrease towards 728 and 734 nm. The data indicate that the spectral absorption of the active Pfr-fraction in green Mougeotia is shifted towards shorter wavelengths as compared to extracted phytochrome from etiolated or even green higher plants. This "blue shift" seems to be typical for Pfr from green lower plants.     

SOME EFFECTS OF LIGHT ON LEAF GROWTH IN PISUM SATIVUM AND TROPAEOLUM MAJUS

Abstract— The effect of wave-length of light on leaf expansion in Tropaeolum majus 'Double Orange Gleam' and Pisurn sativum 'Meteor' has been studied. In both species leaf growth is strongly promoted by light.
Increasing the daily duration of exposure to light increased leaf expansion in Tropueolum in both blue and red wave-bands over a range of light intensities. In Pisum a similar effect of ail increase in duration of irradiation was found over the whole range of intensities used for blue light but only at the highest intensity for red light: at the two lower intensities in red an increase in duration of the light treatment beyond 1 hr did not increase leaf expansion.
In both species a period of 4 hr of blue followed by 4 hr of red promoted leaf growth more than 4 hr of red followed by 4 hr of blue. The effect of a 4 hr period of red light was largely prevented when it was followed by far-red; the effect of 4 hr of blue light, on the other hand, was not affected by subsequent exposure to far-red.
It is concluded that leaf growth in Pisum and Tropaeolum is dependent not only on the 'low-energy' red/far-red reversible reaction but also on one or more 'high-enerFy' photo-reactions.     

PHYTOCHROME AND EFFECTS OF SHADING ON GROWTH OF WOODLAND PLANTS

qrowth of Circaea lutetiaim plants was studied in various locations in or near a mixed deciduous woodland. Morphological changes resulting from increased shading included increases in leaf area ratio, specific leaf area and specific water content. Parallel measurements with a spectroradi-ometer confirmed that shading involved a reduction in both light fluence rate and light quality (e.g. red/far-red ratio). Phytochrome P_fr/P status was also studied by spectrophotometric measurements on Avena seedling test material and by biological (Lactuca seed germination) assay. Attempts were made to demonstrate phytochrome controlled changes in plant morphology under controlled environment, using both end-of-day far-red treatment and far-red enrichment of the main light period. Effects of natural shading were most clearly simulated by varying light fluence rate while maintaining a constant but high red/far-red ratio     

REGULATION OF PROTEIN PHOSPHORYLATION BY PHYTOCHROME IN Sorghum bicolor

Abstract— In vitro phosphorylation of some polypeptides was affected in extracts obtained from 5-and 6-day-old plants irradiated with 5 min of red light. The phosphorylation of 55 kDa polypeptide in both 5- and 6-day-old plants, a 60 kDa, and 76 kDa polypeptide in 6-day-old plants and 70 kDa, 67 kDa polypeptide in 5-day-old plants was stimulated by red light. This effect was reversible by far-red light. The extent of stimulation by red light and reversal by far-red light varied for different polypeptides. No differential effect of red and far-red light was seen on the phosphorylation of 94 and 40 kDa polypeptides. In fact, phosphorylation of 94 kDa polypeptide in 6-day-old plants decreased on red light irradiation. These results show that the phosphorylation or dephosphorylation of some proteins is affected by phytochrome and the effect of light is also dependent on the age of the plant.     

Quantitative study of fluorescence excitation and emission spectra of bean leaves

A quantitative and comprehensive knowledge of leaf fluorescence is required for the interpretation of fluorescence signals at the canopy level and also for the modelling of leaf and canopy fluorescence. In this work we present full range fluorescence excitation and emission spectra of intact leaves, expressed in units of apparent spectral fluorescence yield, from both the adaxial and the abaxial sides of the leaves, and for both front-side and back-side geometries. Emission spectra were measured for incident radiations in the blue and the green spectral range. The red/far-red fluorescence ratio depended on the measurement geometry and on the excitation wavelength. Excitation spectra were measured for emissions at 687 and 760 nm. When the abaxial side was illuminated, the measured spectra always had a larger intensity compared to adaxial side that is explained by the higher scattering of the spongy tissues. At 760 nm, the spectra had the same shape for front-side and back-side geometry, indicating that scattering predominated. At 687 nm, the shape of the spectra was very different for front-side and back-side geometry due to re-absorption of red fluorescence within the leaf. The comparison of excitation spectra measured from the adaxial or the abaxial side revealed differences in carotenoid absorption.     

米蚩酮对酸敏片光谱增感研究

酸敏片是由偏二氯乙烯-丙烯酸甲酯共聚物(简称偏丙树脂)与酸敏指示剂组成的非银记录材料。该体系仅对253.7nm的低压汞灯敏感,用作光学信息记录材料受到限制。为了克服这一缺陷,文献(3)的作者采用米蚩酮增感,使该体系对广泛使用的高压汞灯也敏感。本文试图用吸收光谱法研究该体系中是否有基态电荷转移复.合物生成,通过测定曝光后光谱的变化和光谱响应曲线对其增感机理和实际应用提供一定根据。     

THE ACTION SPECTRUM OF DAPHNIA MAGNA (CRUSTACEA) PHOTOTAXIS IN A SIMULATED NATURAL ENVIRONMENT

Abstract— The action spectrum of phototaxis in Daphnia magna (Crustacea) was measured in a chamber which simulated a natural angular distribution of underwater light. A 17% step-down in irradiance was used to stimulate the phototactic response at all wavelengths and irradiances tested. Peaks in the spectral response curves depended on the fluence rate to which the zooplankton were acclimated. The wavelength of maximum response (Z_max) shifted from yellow-green at the highest acclimation fluence rate (5.1 × 10⁻² Wm⁻²) to blue-violet at moderate rates. At low acclimation fluence rates, the blue-violet maximum was retained and another maximum developed in the red. At the lowest fluence rate (1.6 × 10⁻⁵ Wm⁻²), the blue-violet and red maxima were lost and another maximum developed in the near ultraviolet. The action spectrum indicates the presence of three, and possibly four, photopigments with Z_max, at ∼405, 440, 570 and 690nm. The 440 and 690nm maxima may belong to the same photopigment; however, this was not tested. Changes in zooplankton swimming speed, caused either by large changes in irradiance or by mechanical stimuli, were accompanied by changes in the strength of the phototactic response to the −17% stimulus at any irradiance level for white and monochromatic light, and indicated the presence of a mechanism connecting swimming speed and photosensitivity.     

ANALYSIS OF LIGHT-CONTROLLED ANTHOCYANIN FORMATION IN COLEOPTILES OF Zea mays L.: THE ROLE OF UV-B, BLUE, RED AND FAR-RED LIGHT

Abstract— Light-induced anthocyanin formation in Zea mays L. coleoptiles was investigated in seven different varieties of this species. Under the test conditions, four varieties showed practically no response to any waveband used (UV, continuous red and continuous far-red), two responded strongly to both UV and far-red, and one showed a strong response only to far-red. The radiation-sensitive varieties showed, however, only a very weak response to continuous red light. In those varieties sensitive to far-red light, a pretreatment with continuous red light led to a greatly enhanced response to UV or in one case the manifestation of a response to UV that was previously lacking. Further investigations in one radiation-sensitive variety (INRA) showed that the UV response was to UV-B radiation below 350 nm. The UV response, as well as the far-red and blue responses in this variety, showed fluence-rate dependency. Red light was almost ineffective and showed only a very weak fluence-rate dependency.