Initial phases of gravity-induced lateral auxin transport and geotropic curvature in corn coleoptiles

Summary Wild-type corn coleoptiles showed an initial downward bending upon transfer from the vertical to the horizontal position. Strong upward curvature started only 15–30 min after the begin of horizontal exposure.Little, if any at all, initial downward geotropic bending was found with amylomaize coleoptiles at 1 X g. With stronger stimuli (10 or 20 X g) the amylomaize mutant reacted initially strongly in the wrong direction, i.e. opposite to the later response.When wild-type coleoptiles had been symmetrically prestimulated for 60 min with alternating 2-min horizontal exposures from opposite sides, no initial downward bending occurred if the plane of horizontal exposure was maintained from pretreatment to the continuous horizontal stimulation of the test. If, however, the coleoptiles were rotated 90° around their long axis between pretreatment and test, the initial downward bending reaction developed as in the non-prestimulated controls. Thus changes in reactivity remained localized to the site of stimulation.Following the same pretreatments used for the curvature measurements, lateral ³H-IAA transport was measured in coleoptile segments for 10 or 12.5 min. The auxin distribution found was strikingly parallel to the bending for all pretreatments.The dependence of reaction pattern on the duration of prestimulation in the same plane was tested. The function indicates a half life of 10–20 min for the change in sensitivity. The findings are discussed in view of a model of overstimulation and adaptation.     

The Effects of Red, Far-red, and Blue Light on the Geotropic Response of Coleoptiles of Zea mays

The effects of red, far-red, and blue light on the geotropicresponse of excised coleoptiles of Zea mays have been investigated.Seedlings were grown in darkness for 5 or 6 days, exposed tovarious light treatments, and then returned to darkness fordetermination of the geotropic response. The rate of response of the coleoptiles is decreased after theyhave been exposed to red light (620–700 mµ, 560ergs cm^–2sec^–1 for the 24 hrs, but not for the 4hrs, preceding stimulation by gravity. Furthermore, their rateof response is greatly reduced if they are exposed to red lightfor 10 min and then returned to darkness for 20 hrs before geotropicstimulation. At 25° C an interval of 6 to 8 hrs elapses between a 10-minexposure to red light and the first detectable decrease in thegeotropic response of the coleoptile. This interval can be lengthenedby exposing the seedlings to low temperatures (0° to 2°C) after the light treatment but cannot be greatly shortenedby increasing the duration of exposure to red light. Using a standard procedure of exposing 5-day-old etiolated seedlingsto light for various times, replacing them in darkness for 20hrs and then determining the response of the coleoptiles to4 hrs geotropic stimulation, it has been found that: (a) Exposureto red light for 15 sec significantly decreases the geotropiccurvature of the coleoptiles and that further reduction occurson increasing the length of the light treatment to 2 and 5 min.(b) Far-red light has no effect on the geotropic response ofthe coleoptiles but it can completely reverse the effect ofred light. After repeated alternate exposure to red and far-redlight the geotropic response of the coleoptile is determinedby the nature of the last exposure, (c) Complete reversal ofthe effect of red light by far-red radiation only occurs whenexposure to far-red follows immediately after exposure to red.The reversing effect of far-red radiation is reduced if a periodof darkness intervenes between the red and far-red light treatments,and is lost after a dark interval of approximately 2 hrs. The effect of red light on the rate of geotropic response ofthe coleoptiles is independent of their age and length at thetime of excision. Blue light acts in a similar way to red light, but the seedlingsare less sensitive to blue than to red light. Coleoptiles grown throughout in a mixture of continuous, weak,red, and far-red light have a lower rate of geotropic responsethan etiolated coleoptiles.     

RED LIGHT,AUXIN RELATIONSHIPS,AND THE PHOTOTROPIC RESPONSES OF CORN AND OAT COLEOPTILES

Briggs , Winslow R. (Stanford U., Stanford, Calif.) Red light, auxin relationships, and the phototropic responses of corn and oat coleoptiles. Amer. Jour. Bot. 50(2): 196–207. Illus. 1963.— Red light decreases the phototropic sensitivity of corn (Zea mays Burpee ‘Golden Cross Bantam’) and oat (Avena saliva ‘Victory’) coleoptiles. The decrease is reflected by a shift of the curve ploting log dosage vs. response to higher dosages, as described in the literature. In the absence of red light treatment, 1,000 meter-candle-seconds (mcs) white light induces first negative curvature in oats and almost no curvature in corn, which appears to lack the mechanism for first negative curvature. Immediately following a 2-hr red light treatment, the same white light dosage induces almost maximum first positive curvature both in corn and in oat coleoptiles. The increase in curvature obtained reflects the decreased phototropic sensitivity of both plants shown by the dosage-response curve shift. After red treatment, the effect of red light remains maximal for an hour, decaying to the level of non-red-treated plants within another 2 hr. Red light suppresses auxin production by corn coleoptiles. The effect decays after the end of red treatment. Both changes follow time courses parallel to those for the phototropic sensitivity changes. The 1,000 mcs light dosage induces lateral transport of auxin both in red-treated and untreated corn coleoptiles, despite the lack of curvature of the latter. Red light does not induce a circadian rhythm for the phototropic sensitivity changes in oats, is not effective if administered after phototropic induction, and its effect is probably mediated by phytochrome. The hypothesis, not original with this paper, that red light induces an increase in the amount of pigment mediating second positive curvature most closely accounts for the results obtained. Pertinent literature is discussed.     

Induction of beta-glucosidase activity in maize coleoptiles by blue light illumination

The role of beta-glucosidase during the phototropic response in maize (Zea mays) coleoptiles was investigated. Unilateral blue light illumination abruptly up-regulated the activity of beta-glucosidase in the illuminated halves, 10 min after the onset of illumination, peaking after 30 min and decreasing thereafter. The level of 2,4-dihydroxy-7-methoxy-1,4-benzoxazin-3-one (DIMBOA), which is released from DIMBOA glucoside (DIMBOA-Glc) by beta-glucosidase, and its degradation compound 6-methoxy-benzoxazolinone (MBOA) were elevated within 30 min in the illuminated halves as compare to the shaded halves, prior to the phototropic curvature. Furthermore, beta-glucosidase inhibitor treatment significantly decreased the phototropic curvature and decreased growth suppression in the illuminated sides. These results suggest that blue light induces the activity of beta-glucosidase in the illuminated halves of coleoptiles causing an increase in DIMBOA biosynthesis and the growth inhibition that leads to a phototropic curvature.     

Relation of Phytochrome-enhanced Geotropic Sensitivity to Ethylene Production

Brief exposure of etiolated pea (Pisum sativum cv. Alaska) seedlings to red light enhances subsequent development of geotropic curvature of the stem. Both this response and inhibition of ethylene production by red light become maximal 8 hours after illumination. Very low concentrations of applied ethylene inhibit development of geotropic curvature, whereas hypobaric treatment enhances geotropic sensitivity by removing endogenous ethylene. Increased geotropic sensitivity after illumination is accompanied by increased lateral migration of ³H-indoleacetic acid in response to gravity, and ethylene inhibits this lateral migration. It is suggested, therefore, that red light-enhanced geotropic sensitivity is caused by increased lateral auxin transport resulting from a reduction in ethylene production after illumination.     

Der Einfluss hellroter und dunkelroter Strahlung auf die geotropische Reaktion der Keimlinge vonSinapis alba L

Summary Our experiments indicate that the negative geotropic reactivity of dark-grown mustard seedlings (Sinapis alba L.) is greatly increased when the seedlings are irradiated with visible light. Obviously in irradiated seedlings the geotropic reaction is more rapid and intense. The results of this paper point out that light controls the geotropic behaviour in exactly the same way as morphogenesis. Apparently the increased geotropic reactivity of the irradiated seedlings is only one manifestation of the basic metabolic changes which occur in the dark-grown seedling after the absorption of light and which finally lead to photomorphogenesis.In earlier papers we have been able to show that photomorphogenesis in these mustard seedlings is controlled by two basic photoreactive systems: the reversible red far — red system and the so called blue far — red system. The same, probably, is true for the control of the geotropic reactivity under our standard experimental conditions.

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Mit 4 Textabbildungen     

Geotropic curvature of decapitated Avena coleoptiles after application of tips of maize roots,tips of Avena coleoptiles,indoleacetic acid,or abscisic acid

Isolated Avena coleoptiles were decapitated at different distances from the tip and then placed horizontally, after which the geotropic curvature was measured. No geotropic curvature could be detected during the first 3 h. Later, upward curvature occurred which was found to depend inversely on the length of the decapitated tips. When the tips of maize roots or Avena coleoptiles were placed on the cut surface of decapitated Avena coleoptiles, the coleoptiles showed a significantly stronger upward curvature as compared to controls which had been provided with agar blocks on the cut surface. The same upward curvature was found with decapitated coleoptiles provided with agar blocks containing 10^-6 or 10^-7 M indoleacetic acid (IAA). After application of abscisic acid (ABA) at concentrations of 10^-6 and 10^-8 M to the decapitated coleoptiles, the curvature observed was not different from that of the controls; at higher concentrations of ABA the curvature was found to be lower than that of the controls. It is concluded that root tips secrete a substance which may replace the effect of IAA in coleoptiles. The results are discussed in view of the validity of the Cholodny-Went hypothesis for the geotropic reaction of roots.Abbreviations ABA abscisic acid - IAA 3-indoleacetic acid     

Geotropism and the lateral transport of auxin in the corn mutant amylomaize

Summary In coleoptiles of the amylomaize corn mutant (AM), the amyloplasts are much reduced in size in comparison with the wild type corn (WT), permitting a comparison of geotropic responsiveness as related to lateral displacement of amyloplasts and lateral transport of auxin. The amyloplasts of AM showed 30–40% lesser lateral redistribution in response to horizontal exposure in comparison with WT. With geotropic stimulation, the lateral transport of auxin in the direction of growth was 40–80% less, and the geotropic curvature by the coleoptiles was also significantly less in the mutant as compared with WT. These correlations support the hypothesis that the starch plastids serve as gravity sensors in the geotropic responses of coleoptiles.     

Desensitization by red and blue light of phototropism in maize coleoptiles

The effects of pretreatments with red and blue light (RL, BL) on the fluence-response curve for the phototropism induced by a BL pulse (first positive curvature) were investigated with darkadapted maize (Zea mays L.) coleoptiles. A pulse of RL, giving a fluence sufficient to saturate phytochrome-mediated responses in this material, shifted the bell-shaped phototropic fluence-response curve to higher fluences and increased its peak height. A pulse of high-fluence BL given immediately prior to this RL treatment temporarily suppressed the phototropic fluence-response curve, and shifted the curve to higher fluences than induced by RL alone. The shift by BL progressed rapidly compared to that by RL. The results indicate (1) that first positive curvature is desensitized by both phytochrome and a BL system, (2) that desensitization by BL occurs with respect to both the maximal response and the quantum efficiency, and (3) that the desensitization responses mediated by phytochrome and the BL system can be induced simultaneously but develop following different kinetics. It is suggested that theses desensitization responses contribute to the induction of second positive curvature, a response induced by prolonged irradiation.Abbreviations BL blue light - RL red light CIW-DPB Publication No. 1001     

Effect of indoleacetic acid,abscisic acid,root tips and coleoptile tips on growth and curvature of maize roots

The effect of externally applied indoleacetic acid (IAA) and abscisic acid (ABA) on the growth of roots of Zea mays L. was measured. Donor blocks of agar with IAA or ABA were placed laterally on the roots and root curvature was measured. When IAA was applied to vertical roots, a curvature directed toward the donor block was observed. This curvature corresponded to a growth inhibition at the side of the root where the donor was applied. When IAA was applied to horizontal roots from the upper side, normal geotropic downward bending was delayed or totally inhibited. The extent of retardation and the inhibition of curvature were found to depend on the concentration of IAA in the donor block. ABA neither induced curvature in vertical roots nor inhibited geotropic curvature in horizontal roots; thus the growth of roots was not inhibited by ABA. However, when, instead of donor blocks, root tips or coleoptile tips were placed onto vertical roots, a curvature of the roots was observed.Abbreviations ABA abscisic acid - IAA 3-indoleacetic acid     

Reorientation of microtubules at the outer epidermal wall of maize coleoptiles by phytochrome,blue-light photoreceptor,and auxin

Summary The effects of red and blue light on the orientation of cortical microtubules (MTs) underneath the outer epidermal wall of maize (Zea mays L.) coleoptiles were investigated with immunofluorescent techniques. The epidermal cells of dark-grown coleoptiles demonstrated an irregular pattern of regions of parallel MTs with a random distribution of orientations. This pattern could be changed into a uniformly transverse MT alignment with respect to the long cell axis by 1 h of irradiation with red light. This response was transient as the MTs spontaneously shifted into a longitudinal orientation after 1–2 h of continued irradiation. Induction/reversion experiments with short red and far-red light pulses demonstrated the involvement of phytochrome in this response. In contrast to red light, irradiation with blue light induced a stable longitudinal MT alignment which was established within 10 min. The blue-light response could not be affected by subsequent irradiations with red or far-red light indicating the involvement of a separate blue-light photoreceptor which antagonizes the effect of phytochrome. In mixed light treatments with red and blue light, the blue-light photoreceptor always dominated over phytochrome which exhibited an apparently less stable influence on MT orientation. Long-term irradiations with red or blue light up to 6 h did not reveal any rhythmic changes of MT orientation that could be related to the rhythmicity of helicoidal cell-wall structure. Subapical segments isolated from dark-grown coleoptiles maintained a longitudinal MT arrangement even in red light indicating that the responsiveness to phytochrome was lost upon isolation. Conversely auxin induced a transverse MT arrangement in isolated segments even in blue light, indicating that the responsiveness to blue-light photoreceptor was eliminated by the hormone. These complex interactions are discussed in the context of current hypotheses on the functional significance of MT reorientations for cell development.Abbreviations MT cortical microtubule - P_r, P_fr red and far-red absorbing form of phytochrome     

Effect of red light on the phototropic sensitivity of corn coleoptiles

The effect of red light in alteration of the phototropic sensitivity of corn coleoptiles (Zea mays L., cultivar Burpee Barbecue Hybrid) is investigated. Phototropic dosage-response curves for etiolated coleoptiles are compared with those for coleoptiles receiving 1 hour of continuous red light immediately prior to phototropic induction. In the former case, only curvature comparable to the first positive curvature of oat coleoptiles is obtained. There is no evidence for first negative curvature and only minimal second positive curvature. The reciprocity law proved valid for all curvatures obtained. With red light, the sensitivity of the first positive curvature was decreased over ten-fold and there was clear appearance of second positive curvature for which the reciprocity law was not valid. Once again there was no evidence for negative curvature. Time course studies indicated that within 1 hour of the beginning of red light treatment at 25°, reactions leading to the decrease in phototropic sensitivity of the first positive component had gone to completion whether the red light was continuous or consisted of a single 1 second exposure followed by a 1 hour dark period. An action spectrum for the red-induced change in phototropic sensitivity showed a marked peak near 660 mμ with a small broad shoulder between 610 and 630 mμ, characteristic of phytochrome-mediated responses. The effect of red light could be fully reversed by low dosages of far-red light, but longer doses of far red were less effective. Large dosages of far-red light alone induced the same alteration in phototropic sensitivity as did red light.     

Auxintransport und Phototropismus

Summary Short illumination of excised coleoptiles (with or without apex) inhibits the subsequent transport of IAA-2-¹⁴C in these sections during darkness.To a certain extent the inhibition is dependent both on the light intensity and on the duration of illumination. Only the blue region of the visible spectrum is effective.The light induced inhibition is due to a decrease of the quantity of IAA transported; on the other hand, the velocity of transport remains unchanged.The inhibition of auxin transport can be observed only if coleoptiles contain endogenous or fed auxin during the preceding illumination period. Besides illumination inhibition of auxin transport can also be brought about by incubation of coleoptile sections with a previously illuminated IAA/FMN solution.Auxin transformed by peroxidase operates in the same way. The different oxidation products of IAA in the solutions used were identified: The only product which inhibits elongation growth and auxin transport was 3-M. The conversion of IAA to 3-M is accomplished by crude cell-free extracts from corn coleoptiles.An increased formation of labeled 3-M from IAA-2-¹⁴C during illumination of coleoptiles could be demonstrated.Since 3-M is not actively transported in coleoptiles, it must be assumed that 3-M functions as an inhibitor of auxin transport only at its site of formation.It is concluded that the phototropic curvature of coleoptiles and stems is triggered by the photooxidative formation of 3-M from IAA in the side exposed to light. The flow of growth substances will be partly blocked by 3-M in this side and can be directed to the shaded side.On the strength of these findings some phenomena of phototropism (transmission of stimulus, mneme, quantum yield) can easily be explained.

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Abkürzungen FMN Flayinmononucleotid - IES Indol-3-essigsäure - 3-M 3-Methylenoxindol - NES -Naphthylessigsäure Herrn Prof. Dr. L. Brauner zum 70. Geburtstag in Dankbarkeit gewidmet.     

Blue-light-induced shift of the phototropic fluence-response curve in Pilobolus sporangiophores

The effects of preirradiation with blue light on the shift of the fluence-response curve for the first and the second positive curvatures were examined in Pilobolus crystallinus (Wiggers) Tode sporangiophores. A 1-min preirradiation with blue light at 47 or 960 nmol·m^-2 lowered the fluence-response curve for the first positive curvature and shifted the peak to a higher fluence. The fluence-response curve was shifted back to a lower fluence when a dark period was inserted between the preirradiation and the curvature-inducing light. This shift back to lower fluence was biphasic when the fluence was high (960 nmol · m^-2), indicating the participation of two components in the phototropic reaction for the first positive curvature.The fluence-response curve for the second positive curvature did not seem to be shifted to a higher fluence region when fluence was varied by varying exposure time. However, the fluence-response curve obtained by varying the fluence rate of a 20-min irradiation period indicated that the second positive curvature was also shifted to a higher-fluence region by preirradiation with blue light. A small shoulder appeared on the fluence-response curve when preirradiation at a high fluence rate was given.Abbreviations BL blue light - CIL curvature-inducing light     

The lateral transport of IAA in intact coleoptiles of Avena sativa L. and Zea mays L. during geotropic stimulation

Summary Movement of IAA was studied in excised coleoptile apices and whole seedlings of Zea mays L. and Avena sativa L. during geotropic stimulation. A micropipette technique permitted the application of [5-³H]IAA at predetermined points on the coleoptiles with minimal tissue damage.When [5-³H]IAA was applied to the upper side of a horizontal excised Zea coleoptile, about 60% of the recoverable radioactivity had moved into the lower half after 2 h. In contrast, when application was made to the lower side of a horizontal excised coleoptile, only 4% of the radioactivity migrated to the upper half. There was, thus, a net downward movement of 56%. Similar patterns of distribution were found for radioactivity in both the tissue and the basal receiver blocks. In horizontal shoot tissues of intact Zea seedlings a net downward movement of about 30% of the recoverable radioactivity occurred after 1 h of geotropic stimulation. Comparable experiments with Avena indicated a net downward movement of 6–12% in excised apices of coleoptiles and in the intact shoot. In both Zea and Avena chromatographic analyses of tissue and receiver blocks indicated that the movement of radioactivity reflected that of IAA.In Zea coleoptiles, the lateral migration of radioactivity after 2 h was 3 to 4 times greater in the apical tissues than in the basal tissues. A significant net downward movement of radioactivity was detected after 10 min of geotropic stimulation in the extreme apex of Zea coleoptiles but not in the more basal regions.These experiments show that downward lateral transport of IAA occurs in intact shoots of Zea and Avena seedlings upon geotropic stimulation. Lateral transport of IAA had previously been demonstrated only in sub-apical segments of Zea coleoptiles.     

Interaction of gravi- and phototropic stimulation in the response of maize (Zea mays L.) coleoptiles

The influence of gravitropic stimulation upon blue-light-induced first positive phototropism for stimulations in the same (light source and center of gravity opposite to each other) and in opposing directions was investigated in maize cole-optiles by measuring fluence-response patterns. As a result of gravitropic counterstimulation, phototropic bending was transient with maximum curvature occurring 100 min after stimulation. On a horizontal clinostat, however, the seedlings curved for 20 h. Gravistimulation in the opposite direction acted additively upon blue-light curvature. Gravistimulation in the same direction as phototropic stimulation produced a complex behaviour deviating from simple additivity. This pattern can be explained by a gravitropically mediated sensitization of the phototropic reaction, an optimal dependence of differential growth on the sum of photo-and gravistimulation, and blue-light-induced inhibition of gravitropic curvature at high fluences. These findings indicate that several steps of photo-and gravitransduction are separate. Preirradiation with red light desensitized the system independently of applied gravity-treatment, indicating that the site of red-light interaction is common to both transduction chains.Abbreviations BL blue light - G⁺ stimulation by light and gravity in the same direction (i.e. light source and center of gravity opposite to each other) - G^- stimulation by light and gravity in opposing directions     

Die Dosis-Wirkungsrelationen bei geotroper und phototroper Reizung: Vergleich von Mono- mit Dicotyledonen

Zusammenfassung der Ergebnisse Die geotropen Krümmungen von Avena-Coleoptilen und Lens-Epicotylen nehmen linear proportional der Reizdauer zu. Bei geringen Reizzeiten sind beide Objekte gleich hoch empfindlich; bei längerer Reizdauer krümmen sich die Avena-Coleoptilen etwas stärker. Lens-Epicotyle reagieren auf zunehmende phototrope Reizung mit einer ersten und einer zweiten positiven Krümmung. Zwischen beiden Krümmungsbereichen (etwa von 10 000–1 000 000 lx · sec) sind sie phototropisch unempfindlich. Negative Krümmungen treten, nie auf. Ebenso verhalten sich 12 weitere dicotyle (Brassica napus, Brassica oleracea subsp. capitata, Brassica oleracea subsp. bullata, Lepidium sativum, Vicia villosa, Sinapis alba, Cucumis sativus, Linum usitatissimum, Helianthus annuus, Agrostemma githago, Raphanus sativus, Convolvulus tricolor) und 3 weitere monocotyle (Hordeum distichon, Secale cereale, Triticum aestivum) Pflanzenarten.Die phototrope Empfindlichkeit ist für Avena-Coleoptilen und Lens-Epicotyle im Bereich der ersten positiven Reaktion gleich groß, im Bereich der zweiten positiven Krümmung sind Avena-Coleoptilen empfindlicher. Das Reizmengengesetz ist für Lens-Epicotyle (wie für Avena-Coleoptilen) in der ersten positiven Krümmung gültig, in der zweiten positiven nicht.

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The dose response relations in geotropic and phototropic stimulation: Comparison of mono-with dicotyledonous plants

Summary The increase in the geotropic curvatures of Avena coleoptiles and Lens epicotyls is linear and proportional to the time of stimulation. With low stimulation the sensitivities of both objects are equal; with longer stimulation the curvature of Avena coleoptiles is somewhat greater.To increased phototropic irradiance Lens epicotyls react with a first and a second positive curvature. Between the two ranges of curvature (from about 10,000 up to 1,000,000 lx · sec) they are phototropically insensitive; negative curvatures never occur. The same reaction is shown by 12 other dicotyledonous plants (Brassica napus, Brassica oleracea subsp. capitata, Brassica oleracea subsp. bullata, Lepidium sativum, Vicia villosa, Sinapis alba, Cucumis sativus, Linum usitatissimum, Helianthus annuus, Agrostemma githago, Raphanus sativus, Convolvulus tricolor) and by 3 other monocotyledonous plants (Hordeum distichon, Secale cereale, Triticum aestivum). In the first positive reaction the phototropic sensitivities of Avena coleoptiles and Lens epicotyls are equal, in the second positive reaction Avena coleoptiles are more sensitive. For Lens epicotyls (for Avena coleoptiles, too) the reciprocity law is valid in the first positive reaction, but not in the second positive reaction.

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Aus einer Dissertation der Mathematisch-Naturwissenschaftlichen Fakultät der Universität Rostock (Steyer, 1964).     

Polarographische Messung der Nitritreduktion von Chlorella im monochromatischen Licht

Summary In green plant cells nitrite is reduced by two systems, one dependent on photosynthesis and the other upon respiration. Using a polarographic method for continuous measurement of nitrite uptake, the relationship between light driven and respiration linked nitrite reduction of Chlorella cells was studied.Photosynthetic nitrite reduction is characterized by a pronounced increase in the velocity of nitrite uptake upon illumination. After the light is turned off the velocity immediately returns to the preillumination value. Photosynthetic nitrite reduction of Chlorella is separated from respiration linked nitrite reduction by illumination with red light under anaerobic conditions; it is stimulated by CO₂ and is inhibited by DCMU, findings which confirm earlier observations.In white light a special blue light stimulation of nitrite uptake is overlapped by photosynthetic nitrite reduction. In contrast to photosynthetic nitrite reduction this type of light stimulation is characterized by a lag period of about I min from the onset of illumination; it continues about 10 min when the light is turned off. It is separated from photosynthetic nitrite reduction by irradiation of the algae with low intensities of short wavelength light (<500 nm). Blue light stimulation of nitrite uptake of Chlorella is strongly dependent on the developmental stage of the cells. It is observed with young cells (autospores) of synchronized algae only.There is no evidence for any connection between blue light stimulation of nitrite uptake and photosynthesis. From the sensitivity of this process towards anaerobic conditions and antimycin A it is concluded to be a stimulation of respiration linked nitrite reduction.Under conditions of low exogenous nitrite concentration a temporary inhibition of steady state dark nitrite reduction appears immediately after the light is turned off. From several observations it is concluded that the inhibition already exists during the preceding illumination and decreases the rate of total nitrite uptake in the light. This process is suppressed by inhibition of respiration as well as by the inhibitor of photosynthesis, DCMU.If nitrate is the source of nitrogen an excretion of nitrite is found following illumination. The kinetics of this process agree with those observed for the light induced inhibition of steady state dark nitrite reduction immediately after illumination.     

The Influence of Light on Geotropism in Cress Roots

Light affects the growth and orientation of roots of cress seedlings(Lepidium sativum L. cv. Curled). The effects are manifest eitheras increased rates of geotropic curvature or, if the roots arehorizontal, as distorted and crinkled forms of growth. Blue,red, and far-red irradiation can bring about these effects,but with differences of detail: at equal fluence rates duringthe period of geostimulus, blue is more effective than red atincreasing the rate of geocurvature; however, with irradiationprior to a geostimulus, only the stimulatory effects of redirradiation persist for 2–4 h of darkness. Short periods(5 min) of radiation, if given at the time of geostimulus, enhancegeocurvature, again with blue most, and far-red least, effective,but there are no clear indications of red/far-red reversibility.The possibility of there being more than one photosystem responsiblefor the effects of white light on the geotropic responsivenessof roots is discussed.     

Effects of red light on the fluence–response relationship for pulse-induced phototropism of maize coleoptiles

Dark-adapted coleoptiles of maize (Zea mays L.) were treated with red light (3min at 10.5 μmol m^?2S^?1) and were Stimulated, after a dark interval, with a pulse of unilateral blue light to induce phototropism. Phototropic fluence-response curves were obtained in this way for different dark intervals. It was confirmed that the bell-shaped fluence-response curve for the first pulse-induced positive phototropism (FPIPP) shifts to higher fluences following the red-light treatment, the maximal shift being achieved at a dark interval of 2h. We found, however, that the two arms of the Fluence-response curve do not shift synchronously. The shift of the descending arm to higher fluences began at 15 min. The ascending arm showed a slight shift to lower fluences before a greater shift to higher flucnces. the change of the shift direction occurring at 30–40min. Accordingly, the fluence-response curve obtained for a 30 min dark interval was comparatively wide. Although dark-adapted coleoptiles showed only fPIPP, another bell-shaped fluence-response curve, representing the second pulse-induced positive phototropism (sPIPP), appeared gradually after the red-light treatment. These changes of the phototropic fluence– respnse curve following exposure to red light are likely to have adaptive values because they favour phototropism under brighter light.