Action spectrum for the blue-light-dependent morphogenesis of hair whorls in Acetabularia mediterranea

In young Acetabularia mediterranea Lamouroux (=A. acetabulum (L.) Silva) the formation of the lateral hair whorls can be induced by a short pulse of blue light after continuous red preillumination. In this paper we describe the experimental conditions for optimum response and the properties of the action spectrum. The probit of the cells which eventually form hair whorls is linearly correlated to the logarithm of the incident quanta of blue light. Parallel fluence-response curves for all wavelengths indicate the involvement of only one photoreceptor pigment. The action spectrum shows no effectiveness of wavelengths above 520 nm, a high action peak at 470 nm and two lower ones at 425 and 370 nm, and is in accordance with those of cryptochrome-like photoreceptors.     

Wirkungsspektren der Anthocyansynthese in Gewebekulturen und Keimlingen von Haplopappus gracilis

Summary The biosynthesis of anthocyanin in tissue cultures and intact seedlings of Haplopappus gracilis is a light-dependent reaction which can be induced by blue light only. Anthocyanin appeared in all organs of the seedling.Wounding of the plant led to an increase in the content of anthocyanin due to increased anthocyanin synthesis in the cotyledons.The action spectra of anthocyanin formation in tissue cultures and intact seedlings have two peaks, one at 438 nm and the other at 372 nm. The limit of activity in the direction of longer wavelengths lies between 474 and 493 nm. Red light of short and long wavelength is ineffective in the induction of pigment synthesis. The photoreceptor of the light reaction is supposed to be a yellow pigment (flavoprotein or carotinoid). In contrast to the intact plants, isolated cotyledons and wounded seedlings are able to form anthocyanin not only in the blue region but also during irradiation with red light of high intensity. The action spectrum of anthocyanin synthesis in the isolated cotyledons has a marked maximum at about 440 nm and a second one at about 660 nm. A little activity can be observed throughout the visible spectrum. The pigment synthesis induced by red light can be completely suppressed by DCMU, an inhibitor of photosynthesis. This indicates that in the case of the activity in the red light caused by wounding chlorophyll serves as photoreceptor.The anthocyanin synthesis in tissue cultures and seedlings could not be influenced by low energy radiation in the red or in the far red region, even after induction of anthocyanin synthesis by blue light of high intensity. Therefore it seems that the phytochrome system is not involved in anthocyanin synthesis in Haplopappus gracilis.     

Action spectra for fruiting of the mushroom Coprinus congregatus

Spectral sensitivity for photostimulated and photoinhibited phases of the development of Coprinus congregatus Bull. ex Fr. was determined from 405–730 nm. The cultures were exposed during 12 h to a constant number of incident quanta. Spectral sensitivity for photoinduction of primordia formation, for photoinhibition of primordia development and for photomaturation of primordia was quite similar, suggesting a common photoreceptor during fruit-body morphogenesis. A defined action spectrum for the photoinhibitory effect of a light break during the inductive night was determined from 407–690 nm. The most effective wavelengths were in the blue (445 nm). Wavelengths longer than 510 nm were ineffective. The general shape of this action spectrum was similar to those obtained for many blue light responses in which a flavoprotein was postulated to be the photoreceptor.     

Action Spectrum for the Timing of Photo-Induced Cell Division in Adiantum Gametophytes

The photo-induced cell division in single-celled protonemata of the fern Adiantum capillus-veneris was studied. When the protonemata were exposed to monochromatic light at 50 nm intervals between 350 and 750 nm, irradiations in the blue and near-ultraviolet regions effectively induced cell division, while wavelengths longer than 550 nm showed no such effect. As reciprocity between duration and intensity was observed within the range of incident energy used, the action spectrum for the frequency of the photo-induced cell divisions 24 h after irradiation was determined between 360 and 510 nm at 10 nm intervals. Furthermore, the previously known effect of phytochrome on the timing of the cell division was minimized by a short exposure to red light given immediately after the monochromatic irradiation. The resulting action spectra showed a peak in the neighborhood of 460 nm with shoulders and another peak in the near-ultraviolet region.     

Effect of Light Quality on Stomatal Opening in Leaves of Xanthium strumarium L

Flux response curves were determined at 16 wavelengths of light for the conductance for water vapor of the lower epidermis of detached leaves of Xanthium strumarium L. An action spectrum of stomatal opening resulted in which blue light (wavelengths between 430 and 460 nanometers) was nearly ten times more effective than red light (wavelengths between 630 and 680 nanometers) in producing a conductance of 15 centimoles per square meter per second. Stomata responded only slightly to green light. An action spectrum of stomatal responses to red light corresponded to that of CO₂ assimilation; the inhibitors of photosynthetic electron transport, cyanazine (2-chloro-4[1-cyano-1-methylethylamino]-6-ethylamino-s-triazine) and 3-(3,4-dichlorophenyl)-1,1-dimethylurea, eliminated the response to red light. This indicates that light absorption by chlorophyll is the cause of stomatal sensitivity to red light. Determination of flux response curves on leaves in the normal position (upper epidermis facing the light) or in the inverted position (lower epidermis facing the light) led to the conclusion that the photoreceptors for blue as well as for red light are located on or near the surfaces of the leaves; presumably they are in the guard cells themselves.     

Heterocyst Formation in the Blue-green Alga Anabaens doliolum--A Study of Some Aspects of Photoregulation

Of the different wavelengths of visible spectrum, red light(630–680 nm) supports maximum heterocyst production andits effect depends upon incident energy and the exposure period.The action spectrum of heterocyst formation corresponds withthe absorption spectrum of major photosynthetic pigments. Absenaof carbon dioxide is inhibitory to heterocyst formation, butsugars can partially substitute for carbon dioxide in the light,not in the dark. The inductive effect of red light is not reversedby low or high energy green or far-red. Such results are consistentwith a photosynthetic role of light in heterocyst formation,although a direct activation of some enzymes by light may alsobe of importance. Anabaena dollolum, blue-green alga, heterocyst formation, light     

Species-specific effects on the optical signals of voltage-sensitive dyes

Summary The absorption changes of two merocyanine dyes in response to membrane potential changes were measured on several nueronal preparations to see whether the dyes would be useful in recording from these cells.We were able to record large signals without averaging from barnacle and leech neurons. The greatest signal with WW375 was seen at 750 nm. Much smaller increases in transmitted light intensity were seen at all other wavelengths between 500 and 780 nm. In contrast, vertebrate neuronal preparations produced much smaller signals with an entirely different action spectrum. Essentially the same spectrum was seen in cells of the sympathetic ganglion of the bullfrog,Rana catesbiana, dissociated chick spinal cord neurons, or dissociated rat superior cervical ganglion neurons. In each case an action potential was accompanied by increases in transmitted light intensity between 500 and 600 nm and 730 and 780 nm, and decreases in intensity between 600 and 730 nm with the dye WW375, the best dye tested. Similar results were obtained with dye NK2367 on both vertebrate and invertebrate preparations, except that the spectral properties were shifted 30 nm towards the blue. Both dyes caused some photodynamic damage to the cultured neurons after a few minute's exposure to the illuminating light. Several analogues of these dyes were also tried, but did not produce larger signals.     

The ultraviolet action spectrum for stomatal opening in broad bean

The ultraviolet action spectrum for stomatal opening was measured using epidermal peels from leaves of broad bean (Vicia faba). The spectrum was calculated from hyperbolic fluence response curves using 11 wavelengths ranging from 275 to 459 nm. The action spectrum exhibits a major peak at approximately 280 nm and a minor peak at approximately 360 nm. The response at 280 nm is about three times greater than the response at 459 nm. Under the conditions utilized (i.e. the absence of saturating red light), stomatal opening saturated at extremely low fluence rates: <0.2 μmol m⁻² s⁻¹ at 280 nm, and approximately 1.0 μmol m⁻² s⁻¹ at 459 nm. The threshold for blue-light-induced stomatal opening was approximately 0.02 μmol m⁻² s⁻¹. In light-mixing experiments, the addition of 280 nm light to saturating 650 nm (red) light caused additional stomatal opening, which is indicative of separate photoreceptors. In contrast, adding 280 nm of light to saturating 459 nm (blue) light did not increase stomatal opening, suggesting that they both excite the same receptor. The results with white light were similar to those with blue light. We infer that ultraviolet light acts via the blue light photoreceptor rather than through photosynthesis. The additional absorbance peak at 360 nm suggests that the chromophore is either a flavin or a cis-carotenoid, both of which exhibit peaks in this region. It is proposed that the chromophore can be excited either directly by blue light or by energy transferred from the protein portion of the protein-pigment complex after it absorbs 280 nm light.     

Discovery of signaling effect of UV-B/C light in the extended UV-A/blue-type action spectra for step-down and step-up photophobic responses in the unicellular flagellate algaEuglena gracilis

Summary Cultures of unicellular algal flagellateEuglena gracilis grown in different conditions were subjected to action spectroscopy for step-down and step-up photophobic responses, respectively. The spectral region was extended into the UV-B/C as well as in the UV-A and visible regions with the Okazaki Large Spectrograph as the monochromatic light source. The photophobic responses of the cells were measured with an individual-cell assay method with the aid of a computerized video motion analyzer. In the UV-A and visible regions, the shapes of the action spectra were the so-called UV-A/blue type. In the newly studied UV-B/C region, new action peaks were found at 270 nm for the step-down response and at 280 nm for the step-up one. The absorption spectrum of flavin adenine dinucleotide (FAD) appeared to fit the action spectrum for the step-up response, whereas the shape of the step-down action spectrum, which has a UV-A peak (at 370 nm) higher than the blue peak (at 450 nm), appeared to be mimicked by the absorption spectrum of a mixed solution of 6-biopterin and FAD. These observations might also account for the fact that the UV-B/C peak wavelength at 270 nm of the action spectrum for the step-down response is shorter by 10 nm than the action spectrum for the step-up response at 280 nm.Abbreviations FAD flavin adenine dinucleotide - FWHM spectral full width at half maximum - NIBB National Institute for Basic Biology - OLS Okazaki Large Spectrograph - PFB paraflagellar body - UV-A ultraviolet light of spectral region between 320 and 400 nm - UV-B/C ultraviolet light of spectral region between 190 and 320 nm     

Phototactic behaviour in Aphidius gifuensis (Hymenoptera:Braconidae)

We investigated the spectral sensitivity and response to light intensity of Aphidius gifuensis (Hymenoptera: Braconidae), a key natural enemy of the green peach aphid, Myzus persicae (Hemiptera: Aphididae). We used 15 monochromatic lights (emitting various specific wavelengths from 340 to 689 nm) and white light. Monochromatic light of different wavelengths and white light elicited photopositive behaviour from A. gifuensis. The strongest response was stimulated by blue light (492 nm), which induced a movement of 43.5 cm, a response that differed from all other groups. This was followed by green light (568 nm) and UV-light (380 nm). There was no significant response to orange light (601 nm) or red light (649, 668 and 689 nm) from A. gifuensis. The response intensity curve for A. gifuensis to monochromatic light (492 nm) decreased as light intensity increased. At 568 nm, the phototactic response showed an ‘S’ shaped curve. But at 628 nm, the phototactic response rose continuously with increasing intensity. We report here that the visual system of A. gifuensis is composed of three spectrum receptors, attuned to UV, blue and green light. While light intensity is a key factor in determining the photopositive response of A. gifuensis, the effect of intensity varies by wavelength.     

Eine fördernde Wirkung von Blaulicht auf die Carotinoidbildung einer gelben Chlorella-Mutante

Summary In growing as well as in resting cells of a chlorophyll-free yellow mutant of Chlorella vulgaris (211-11h/20) synthesis of carotenoids is enhanced by blue light. Permanent irradiation is necessary to maintain the effect (Fig. 2). At wavelengths around 454 nm the additional carotenoid production is half-saturated at about 1000 erg cm^-2s^-1 and saturated at about 4000 erg cm^-2s^-1 (Fig. 3). An action spectrum exhibits highest efficiency of wavelengths around 465 and 370 nm, a minimum near 400 nm and inefficacy of yellow, red and far-red light (Fig. 4). This wavelength dependence resembles those of light enhanced O₂-uptake, carbohydrate consumption and gain of organically bound nitrogen by the organism.     

Phototropism of Thalli and Rhizoids Developed from the Thallus Segments of Bryopsis hypnoides Lamouroux

Newly regenerated thalli were used to study the phototropism of Bryopsis hypnoides Lamouroux under different qualities of light. Positive phototropism in the thalli and negative phototropiam In the rhizoida of B. hypnoides were investigated and analyzed in terms of bending. Both thaiii and rhlzoids developed from thallus segments exhibited typical tip growth, and their photoreceptive sites for phototroplam were also restricted to the apical hemisphere. The bending curvature of rhizoids and thalli were determined with unilateral lights at various wavelengths and different fluence rates after a fixed duration of Illumination. The trends of bending from the rhizoid and thallus were coincident, which showed that the action spectrum had a large range, from ultraviolet radiation （366.5 nm） to green light （524 nm）. Based on the bending curvatures, blue light had the highest efficiency, while the efficiency of longer wavelengths （〉500 nm） was significantly lower. External Ca^2＋ had no effect on the bending curvature of thalli and rhlzolda. Blue light （440 nm） induced thallus branching from rhizoids, while red light （650 nm） had no such effect. Fast-occurring chloroplast accumulation In the outermost cytoplasmic layer of the blue light （440 nm）-Irradiated region In the rhizoid was observed, from which protrusions （new thalli） arose after 4 h of the onset of illumination, and this action was thought to be driven by the dynamics of actin microfilamenta.     

Action spectra of phototactic responses of the flea beetle, Phyllotreta striolata

Abstract.  Adult flea beetles, Phyllotreta striolata , show a strong positive phototactic response. The action spectrum of phototaxis of dark-adapted beetles was measured with minimal required light intensity between the wavelength range of 300 nm and 600 nm. Male and female flea beetles showed identical phototacitc behaviours. The beetles were most sensitive to light with peak wavelengths between 350 nm and 430 nm in the morning. In the afternoon and evening, the sensitivity to wavelengths shorter than 430 nm decreased, but they remained most sensitive to 430 nm. These results suggest that changes in sensitivity of the photoreceptors or nervous integration influence the phototactic responses, and that the blue wavelengths are more attractive than others.     

Das Wirkungsspektrum der lichtabhängigen Zonierung der Koremien von zwei Mutanten von Penicillium claviforme Bainier

Summary An action spectrum of light induced coremia-zonation was obtained for the fungus Penicillium claviforme mut. olivicolor Abe et Ura. Zonation is induced only by light of wavelengths shorter than 510 nm. The action spectrum has maxima at 370 nm and at 450–460 nm and a definite shoulder at 470–480 nm. Penicillium claviforme mut. album is somewhat less sensitive to light but possesses the same spectral sensitivity.Measurable amounts of carotenoids are not found in the mycelium. The presence of diphenylamine in the nutrition medium has no effect on the fungal sensitivity to light. It is therefore assumed that the photoreceptor pigment involved is a flavoprotein.

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Die Arbeit wurde während eines Studienaufenthaltes im Zentralinstitut für Genetik und Kulturpflanzenforschung der Deutschen Akademie der Wissenschaften zu Berlin in Gatersleben angefertigt.     

STIMULATION OF LIGHT-SATURATED PHOTOSYNTHESIS IN LAMINARIA (PHAEOPHYTA) BY BLUE LIGHT1

The light-saturated rate of photosynthesis in blue light was 50-100% higher than that in red light for young sporophytes of Laminaria digitata (Huds.) Lamour., although photosynthetic rates were slightly higher in red than in blue light at low irradiances. Short exposures to low irradiances (e.g. 2 min at 20 μmol · m^?2· s^?1) of blue light also stimulated the subsequent photosynthesis of Laminaria sporophytes in saturating irradiances of red light but had little effect on photosynthesis in low irradiances of red light. The full stimulatory effect of short exposures to blue light was observed within 5 min of the blue treatment and persisted for at least 15 min in red light or in darkness. Thereafter, the effect began to decline, but some stimulation was still detectable 45 min after the blue treatment. The degree of stimulation was proportional to the logarithm of the photon exposure to blue light over the range 0.15-2.4 mmol · m^?2, and the effectiveness of an exposure to 0.6 mmol · m^?2at different wavelengths was high at 402-475 nm (with a peak at 460-475 nm) but declined sharply at 475-497 nm and was minimal at 544-701 nm. Blue light appears, therefore, to exert a direct effect on the dark reaction of photosynthesis in brown algae, possibly by activating carbon-fixing enzymes or by stimulating the uptake or transport of inorganic carbon in the plants.     

Light-induced chloroplast rearrangements and their action spectra as measured by absorption spectrophotometry

Summary A new combination technique of using both dual-wavelength and opalglas methods for scanning translucent biological samples was applied to leaves of terrestrial plants in order to observe their absorption changes by irradiation and the action spectra for the absorption changes. The measurements of true absorption, free from various effects of scattering, by this technique showed an increase of absorption by weak blue light and a decrease of absorption by strong blue light for almost all of the leaves of 20 plant species examined. These weak- and strong-light responses in absorption were reversible. The fractional increase and decrease of absorbance at 678 nm by weak and strong light were highest, +20% and -31%, for leaves of Begonia semperflorens Link et Otto, and +12% and -13% for leaves of foxtail, Setaria viridis (L.) Beauv., the species examined in further experiments. The response to strong light proceeded to completion earlier than did that to weak light. The strong-light response could be observed separately from the weak-light response by using a leaf pre-irradiated with weak blue light. The responses were measured as a function of light intensity by scanning a single leaf irradiated locally at different intensities, and the action spectra for these responses were measured by scanning a leaf irradiated locally at different wavelengths but at identical intensities. The action spectra for these opposite responses were similar, and showed a band at 450 nm with shoulders but no band in the red region. Microscopic observations of chloroplasts in leaves during irradiation indicated that these changes in absorption are mostly due to rearrangements of chloroplasts in cells caused by irradiation.     

The Effect of Monochromatic Light on α-Linolenic and Trans-3-Hexadecenoic Acids Biosynthesis, and Its Correlation to the Development of the Plastid Lamellar System

Seven day old etiolated Zea mays L. (cv. Wisconsin 355) seedlings were illuminated for 20 h under monochromatic radiations (100 Á pass band) produced by a spectral illuminator of high energy. Four regions of the visible spectrum were observed to stimulate chlorophyll synthesis. With poorly developed leaves (grown for 7 days at 22°C: experiment A). the most efficient wavelengths were found to be in the blue and green (between 445 and 505 nm). yellow (between 580 and 605 nm) and red (maximum 650 nm) parts of the spectrum. With well developed leaves (grown for 7 clays al 27°C: experiment B), a slight displacement of the maxima towards shorter wavelengths was observed. ¹⁴C-acetate was furnished to illuminated maize seedlings to follow lipid synthesis during greening. In the leaves of experiment A, the biosynthesis of α-linolenic acid and monogalactosyldiacylglycerol followed chlorophyll accumulation. In the more developed leaves of experiment B. containing higher amounts of galactolipids, the biosynthesis of α-linolenic acid and monogalactosyldiacylglycerol followed chlorophyll accumulation only in blue and yellow light. The biosynthesis of trans-3-hexadecenoic acid was strictly dependent on the wavelength of the irradiating light in the leaves of experiment A; it was optimal under blue (420 nm) and still very high under yellow (580 nm) and red (650 nm). In the more developed leaves of experiment B, it was optima in blue (445 nm) and in yellow (580 nm), and the red maximum was shifted to 630 nm. All C-trans-3-hexadecenoic acid was incorporated into phosphatidylglycerol. A marked relationship was observed between the intensity of galactolipid synthesis and the development of the lamellar system of maize plastids during greening. A positive correlation could be established between the biosynthesis of trans-3-hcxadeccnoie acid and the development of well constituted grana stacks in the plastids.     

Blue Light Inhibits Mitosis in Tissue Culture Cells

Irradiation of the mitotic (prophase and prometaphase) tissue culture PK (pig kidney embryo) cells using mercury arc lamp and band-pass filters postponed or inhibited anaphase onset. The biological responses observed after irradiation were: (i) normal cell division, (ii) delay in metaphase and then normal anaphase and incomplete cytokinesis, (iii) exit into interphase without separation of chromosomes, (iv) complete mitotic blockage. Cell sensitivity to the light at wavelengths from 423 and 488 nm was nearly the same; to the near UV light (wavelength 360 nm) it was 5–10 times more; to the green light (wavelength >500 nm) it was at least 10 times less. To elucidate the possible mechanism of the action of blue light we measured cell adsorption and examined cell autofluorescence. Autofluorescence of cytoplasmic granules was exited at wavelengths of 450–490 nm, but not at >500 nm. In mitotic cells fluorescent granules accumulated around the spindle. We suppose blue light irradiation induces formation of the free radicals and/or peroxide, and thus perturb the checkpoint system responsible for anaphase onset.     

Blue light effects on rose photosynthesis and photomorphogenesis

Through its impact on photosynthesis and morphogenesis, light is the environmental factor that most affects plant architecture. Using light rather than chemicals to manage plant architecture could reduce the impact on the environment. However, the understanding of how light modulates plant architecture is still poor and further research is needed. To address this question, we examined the development of two rose cultivars, Rosa hybrida‘Radrazz’ and Rosa chinensis‘Old Blush’, cultivated under two light qualities. Plants were grown from one‐node cuttings for 6 weeks under white or blue light at equal photosynthetic efficiencies. While plant development was totally inhibited in darkness, blue light could sustain full development from bud burst until flowering. Blue light reduced the net CO₂ assimilation rate of fully expanded leaves in both cultivars, despite increasing stomatal conductance and intercellular CO₂ concentrations. In ‘Radrazz’, the reduction in CO₂ assimilation under blue light was related to a decrease in photosynthetic pigment content, while in both cultivars, the chl a/b ratio increased. Surprisingly, blue light could induce the same organogenetic activity of the shoot apical meristem, growth of the metamers and flower development as white light. The normal development of rose plants under blue light reveals the strong adaptive properties of rose plants to their light environment. It also indicates that photomorphogenetic processes can all be triggered by blue wavelengths and that despite a lower assimilation rate, blue light can provide sufficient energy via photosynthesis to sustain normal growth and development in roses.