Light effects on in vitro rooting of pear cultivars of different rhizogenic ability

The effect of varying light regimes on in vitro rooting of microcuttings of two pear (Pyrus communis L.) cultivars was investigated. Cultures of the easy to-root Conference and the difficult-to-root Doyenne d'Hiver were incubated for 21 days with or without indole-3-butyric acid (IBA) in the medium in darkness or under continuous far-red (8 µmol m^–2 s^–1), blue, white or red (15 or 36 µmol m^–2 s^–1) light. Conference rooted without IBA when exposed to red, blue or white light while no rooting was observed under far-red light and in darkness. The high rooting efficiency under red and, by contrast, the inhibition under far-red light and darkness suggest the involvement of the phytochrome system in rhizogenesis. The addition of IBA to the culture medium enhanced root production under all light regimes in both cultivars. Red light, especially at the lower photon fluence rate, had a positive effect by increasing root extension (number × length of roots) and stimulating secondary root formation.Abbreviations IBA Indole-3-butyric acid - R red light - B blue light - FR far-red light - W white light - D darkness - P_fr active (far-red light absorbing) form of phytochrome - P_tot total phytochrome - BA benzyl-adenine     

Phytochrome-mediated germination control of maize caryopses

Maize caryopses sown in water germinate equally well either in darkness or under any light regime. However, when they are imbibed in mannitol solutions, continuous far-red light proves to be strongly inhibitory on the final germination as compared to darkness. Similar but less pronounced inhibition is also exhibited by continuous red or blue light. Intermittent far-red light can partially substitute for continuous far-red light in inhibiting maize caryopsis germination, and its effect is reversed to the intermittent red light level when red light is given immediately after each far-red illumination. These results are interpreted as a proof of existence and involvement of phytochrome in the germination control of maize caryopses, though its manifestation is realized only under osmotic stress.Abbreviations D darkness - FR far-red - R red - B blue - c-FR, c-R, c-B continuous FR, R, B, resp. - i-FR, i-R intermittent FR, R, resp.     

Oak Seedlings Grown in Different Light Qualities

Seedlings of oak (Quercus robur) were germinated in darkness for 3 weeks and then given continuous light or short pulses of light (5–8 min every day). The morphological development was followed during 25 days. In continuous white, blue, and red light the stem growth terminated after about 10 days by formation of a resting bud. At that time the seedlings were about 100 mm high. In con tinuous long wavelength farred light (wavelength longer than 700 nm) the stem growth including leaf formation was continuous without the formation of resting buds, and the stem length was about 270 mm after 25 days. The number of nodes developed became twice that of the seedlings grown in while light. The leaves became well developed in all light colours, but leaf areas were largest in plants cultivated in white light. Compared to dark grown seedlings the mean area per leaf was increased about five times in continuous long wavelength far red light. A supplement with short (5 min) pulses of red light each day increased the leaf area up to 20 times. The stem elongation showed a high energy reaction response, i.e. the stem length increased only in continuous long wavelength far-red light but was not influenced by short pulses of red light or far-red light. The leaf expansion, however, was increased by short pulses of red light with a partial reversion of the effect by a subsequent pulse of far-red light. The fraction of the plant covered with periderm was higher in plants given continuous light. In respect to periderm inhibition continuous long wavelength far red light was the most effective. The transfer of seedlings from darkness to continuous white light gave anthocyanin formation in the stem 10–20 mm below the apex. This formation took place in the cortex and was evident in plants grown in darkness or under short pulses of light. Plants grown in continuous red, blue or long wavelength Far red light showed only traces of anthocyanin.     

Effects of Colchicine and Light on Cell Form in Fern Gametophytes. Implications for a Mechanism of Light-induced Cell Elongation

Spores of the fern, Onoclea sensihilis L., suffer a disruption of normal development when they are cultured on media containing colchicine. Cell division is inhibited, and the spores develop into giant spherical cells under continuous white fluorescent light. In darkness only slight cell expansion occurs. Spherical cell expansion in the light requires continuous irradiation. Photosynthesis does not seem to be involved, since variations in light intensity do not affect the final cell diameter; the addition of sucrose to the medium does not permit cell expansion in darkness; and the inhibitor DCMU does not block the light-induced cell expansion. Continuous irradiation of colchicine-treated spores with blue, red or far-red light produces different patterns of cell expansion. Blue light permits spherical growth, similar to that found under white light, whereas red and far-red light promote the reestablishment of polarized filamentous growth. Although ethylene is unable to induce polarized cell expansion in colchicine-treated spores in darkness or white and blue light, it enhances filamentous growth which already is established by red or far-red irradiation. Both red and far-red light increase the elongation of normal filaments (untreated with colchicine) above that of dark-grown plants, but under all 3 conditions the rates of volume growth are identical. Light, however, does cause a decrease in the cell diameters of irradiated filaments. These data are used to construct an hypothesis to explain the promotion of cell elongation in fern protonemata by red and far-red light. The model proposes light-mediated changes in microtubular orientation and cell wall structure which lead to restriction of lateral cell expansion and enhanced elongation growth.     

ΔpH-Dependent Photosystem II Fluorescence Quenching Induced by Saturating, Multiturnover Pulses in Red Algae

We have previously shown that in the red alga Rhodella violacea, exposure to continuous low intensities of light 2 (green light) or near-saturating intensities of white light induces a ΔpH-dependent PSII fluorescence quenching. In this article we further characterize this fluorescence quenching by using white, saturating, multiturnover pulses. Even though the pulses are necessary to induce the ΔpH and the quenching, the development of the latter occurred in darkness and required several tens of seconds. In darkness or in the light in the presence of 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone, the dissipation of the quenching was very slow (more than 15 min) due to a low consumption of the ΔpH, which corresponds to an inactive ATP synthase. In contrast, under far-red illumination or in the presence of 3-(3,4-dichlorophenyl)-1,1′-dimethylurea (only in light), the fluorescence quenching relaxed in a few seconds. The presence of N,N′-dicyclohexyl carbodiimide hindered this relaxation. We propose that the quenching relaxation is related to the consumption of ΔpH by ATP synthase, which remains active under conditions favoring pseudolinear and cyclic electron transfer.     

Different actions of red and blue or far-red lights in the photoperiodic tuberization of Begonia evansiana

The spectral dependence of Begonia evansiana in supplementarylight periods of photoperiodic tuberization and sprouting wasinvestigated. Supplementary application of red light inhibitedtuber development, thereby stimulating vegetative growth. Supplementaryblue or far-red light also suppressed tuber development, butbarely stimulated vegetative growth. However, both red and blue light, given at 6°C during themain light period or the supplementary light period, permittedthe tuberization under the subsequently given conditions ofeither long-days or darkness at 23°C. Blue light appliedafter 5-days of irradiation with white light at 10°C, showedalmost the same action as far-red light, which suppressed tuberizationin darkness. The nature and function of the pigments concernedin the photoperiodic responses are discussed. (Received October 11, 1968; )     

Light Control of Anthocyanin Biosynthesis in Zea Seedlings

Evidence for involvement of two non-photosynthetic pigments in photoinduction of anthocyanin biosynthesis in the roots and mesocotyls of Zea mays L. seedlings is presented. Short (5 min), low energy (4.5 × 10³ J m^?2) fluences of red light neither induced anthocyanin synthesis nor enhanced phenylalanine ammonia-lyase activity in dark-grown maize seedlings. Little anthocyanin synthesis and no enhancement of phenylalanine ammonia-lyase activity was induced by continuous far-red light. Continuous white or blue light induced both anthocyanin synthesis and enhanced phenylalanine ammonia-lyase activity. These results show that phytochrome alone cannot induce anthocyanin synthesis in maize seedlings. However, a strong phytochrome mediation of white light induced pigment synthesis was demonstrated. This effect was not demonstrable with white light enhanced phenylalanine ammonia-lyase activity, indicating that phytochrome controls another step in anthocyanin biosynthesis.     

The germination characteristics of phytochrome-deficient aurea mutant tomato seeds

The role of light reactions in anthocyanin synthesis was studied in both attached and detached corollas of Petunia hybrida (cv. Hit Parade Rosa), the latter grown in vitro in media containing 150 m M sucrose and 50 μ M gibberellic acid (GA). Light was essential for the synthesis of anthocyanin in detached corollas, whereas in intact corollas its effect was only to enhance anthocyanin synthesis. Continuous white light at a fluence rate of at least 20 μmol m⁻² s⁻¹ was needed for anthocyanin synthesis in detached corollas. Blue light was more effective than red or green, and far-red was ineffective. Pigmentation of detached corollas exposed to light was inhibited by the photosynthetic inhibitor 3-(4-dichlorophenyl)-1,1-dimethylurea (DCMU). The chloroplast uncoupler NH₄Cl did not affect anthocyanin synthesis, which was, however, inhibited by the blocking of ATP synthesis in both the chloroplast and the mitochondria by dicyclohexylcarbodiimide (DCCD). Sucrose uptake in vitro was inhibited by DCMU and by darkness, and was promoted equally by blue and red light. The activity of phenylalanine ammonialyase (EC 4.3.1.5) was inhibited in detached corollas grown in the dark or in the light in the presence of DCMU. The activity of chalcone isomerase (EC 5.5.1.6) was not affected by light. These findings suggest that at least two different light reactions are involved in the regulation of anthocyanin synthesis in petunia corollas, namely the high irradiance reaction (HIR) and photosynthesis.     

Photoperiod and light quality effects on rate of dark respiration and on photosynthetic capacity in developing seedlings of Chenopodium rubrum

Development and acclimation of energy transduction were studied in seedlings of Chenopodium rubrum L. ecotype selection 184 (50° 10' N; 105° 35' W) in response to photomorphogenic and photoperiodic treatments. Dark respiration and photosynthetic capacity [nmol O₂ (pair of cotyledons)⁻¹ h⁻¹] were measured with an oxygen electrode. Changes in chloroplast ultrastructure were analyzed concomitantly. After germination, seedlings were grown at constant temperature either in darkness or in continuous light (white, red, far-red and blue) or were subjected to diurnal cycles of light/dark or changes in light quality. Dark respiration was low in far-red light treated seedlings. In red light treated seedlings dark respiration was high and the mean value did not depend on fluence rate or photoperiod. Blue light stimulated transitorily and modulated dark respiration in photoperiodic cycles. Photosynthetic capacity was reduced by far-red light and increased by red light. In response to blue light photosynthetic capacity increased, with indications of a requirement for continuous energy input. Phytochrome and a separate blue light receptor seemed to be involved. In continuous red light a clear cut circadian rhythm of dark respiration was observed. Blue light had a specific effect on chloroplast structure.     

An unusual effect of the far-red absorbing form of phytochrome: Photoinhibition of seed germination inBromus sterilis L.

Seeds ofBromus sterilis L. germinated between 80–100% in darkness at 15° C but were inhibited by exposure to white or red light for 8 h per day. Exposure to far-red light resulted in germination similar to, or less than, that of seeds maintained in darkness. Germination is not permanently inhibited by light as seeds attain maximal germination when transferred back to darkness. Germination can be markedly delayed by exposure to a single pulse of red light following 4 h inhibition in darkness. The effect of the red light can be reversed by a single pulse of far-red light indicating that the photoreversible pigment phytochrome is involved in the response. The response ofB. sterilis seeds to light appears to be unique; the far-red-absorbing form of phytochrome (Pfr) actually inhibiting germination.Abbreviations Pr red absorbing form of phytochrome - Pfr far-red absorbing form of phytochrome     

Adventitious shoot regeneration from Begonia × erythrophylla petiole sections is developmentally sensitive to light quality

The influence of light quality on organogenesis in vitro was investigated using Begonia  ×  erythrophylla petiole explants. Pre-treatment of in vitro donor plants by growth in the dark or under far-red or blue light reduced their competence for shoot formation when compared with those grown under red or white light. Culture of competent petiole explants under far-red, blue light or in the dark reduced the number of shoots produced per explant compared to those cultured under red or white light. Explants were found to be developmentally sensitive to both far-red and blue light, because meristem, but not primordia development was inhibited. In addition, blue light inhibition of shoot formation is not mediated directly through phytochrome, as few shoots formed on explants cultured under a mixture of red and blue light which resulted in a high P _fr/ P _tot (0.82) and would allow shoot formation in the absence of blue light. Unlike the inhibitory influence of far-red light, which is reversible, exposure to blue light permanently reduces an explant's competence for shoot formation. Our results suggest that phytochrome and an independent blue light photoreceptor, possibly a cryptochrome, can regulate shoot production from B. erythrophylla petiole explants.     

Light germination ofAnthoceros miyabeanus spores

The effects of light on the spore germination of a hornwort species,Anthoceros miyabeanus Steph., were investigated. Spores of this species were photoblastic, but their sensitivities to light quality were different. Under either continuous white, red or diffused daylight, more than 80% of the spores germinated, but under blue light none or a few of them germinated. Under continuous far-red light or in total darkness, the spores did not germinate at all.Anthoceros spores required red light irradiation for a very long duration, i.e., over 12–24 hr of red light for saturated germination. However, the spore germination showed clear photo-reversibility by repeated irradiation of red and far-red light. The germination pattern clearly varied with the light quality. There were two fundamental patterns; (1) cell mass type in white or blue light: spores divide before germination, and the sporelings divide frequently and form 1–2 rhizoids soon after germination, and (2) germ tube type in red light: spores germinate without cell division, and the single-cell sporelings elongate without cell division and rhizoid formation.     

The Spectral Sensitivity of Light-induced Leaf Movements

White, blue, green, red, and deep red illumination were usedto shorten a dark period for plants of Bauhinia monandra under12 hour: 12 hour alternations of white light and darkness. Redalone imitated the effect of white light in advancing the cycleof leaf movement. Deep red did not counteract the effect ofprevious illumination with white light.     

PHOTOMORPHOGENESIS IN PTERIS VITTATA: I. PHYTOCHROME-MEDIATED SPORE GERMINATION AND BLUE LIGHT INTERACTION

1. Spores of the fern Pteris vittata did not germinate under totaldark conditions, while an exposure of the spores to continuouswhite light brought about germination. The germination was mosteffectively induced by red light and somewhat by green and far-red,but not at all by blue light. The sensitivity of spores to redlight increased and leveled off about 4 days after sowing at27–28. The promoting effect of red light could be broughtabout by a single exposure of low intensity. Far-red light givenimmediately after red light almost completely reversed the redlight effect, and the photoresponse to red and far-red lightwas repeatedly reversible. The photoreversibility was lost duringan intervening darkness between red and far-red irradiations,and 50% of the initial reversibility was lost after about 6hr of darkness at 27–28. These observations suggest thatthe phytochrome system controls the germination of the fernspore.
2. When the imbibed spores were briefly exposed to a low-energyblue light immediately before or after red irradiation, theirgermination was completely inhibited. The blue light-inducedinhibition was never reversed by brief red irradiation givenimmediately after the blue light. The escape reaction of redlight-induced germination as indicated by blue light given aftervarious periods of intervening darkness was also observed, andits rate was very similar to that determined by using far-redlight. Spores exposed to blue light required 3 days' incubationin darkness at 27–28 to recover their sensitivity tored light. The recovery in darkness of this red sensitivitywas temperature-dependent. It is thus suggested that an unknownbluelight absorbing pigment may be involved in the inhibitionof phytochrome-mediated spore germination.

(Received August 21, 1967; )     

Photocontrol of Growth, and of Anthocyanin and Chlorogenic Acid Production in Cultured Callus Tissues of Haplopappus gracilis

Cultures of dark-grown Haplopappus callus (strain AI) were exposedto continuous blue, green, red, far-red, and white light for33 days at energy levels of approximately 10 J m^-2s^-1. Growthwas suppressed in all but far-red. Blue had the greatest suppressiveeffect, green the least; red and white were about equally effective.Mean cell generation times were increased from 8–8 days(dark control) to 12.5 days in red light and 20.5 days in blue.There was a slight increase in mean wet weight per cell in bluelight but a slight decrease in red, whereas there was almosta twofold increase in mean dry weight per cell in blue and littlechange in red. In contrast, far-red stimulated growth; the meancell generation time was reduced to 6–5 days and therewas little change in wet or dry weight per cell. Anthocyanin synthesis was promoted by all wavebands except far-red.Blue had the greatest effect, then white, red, and green inthat order. In blue light the pigments accumulated rapidly,but only during the early stages of culture. The maximum amountper cell was attained after 7 days and thereafter the valuesdeclined. In red, however, the pigments accumulated relativelyslowly, and the maximum cell content was not attained until22 days; the amount attained was less than half that attainedin blue light. Initially, the ratio of cyanidine-3-glucosideto cyanidine-3-rutinoside exceeded 5.0 in blue light, but theratio fell to almost unity with time. This probably reflecteda rapid initial synthesis of the glucoside accompanied by asteady conversion to the rutinoside. Blue light was also more effective than red in acceleratingchlorogenic acid production. The response to blue light occurredafter the initial rise in anthocyanins and continued for therest of the culture period. The data are discussed in relation to similar high-energy photoresponsesreported for intact systems.     

The 'end-of-day' phytochrome control of internode elongation in mustard: kinetics, interaction with the previous fluence rate, and ecological implications

Abstract The ‘end-of-day’ phytochrome control of internode growth was characterized in Sinapis alba, seedlings previously grown under continuous white light for 13 d. The transition from white light to darkness caused a reduction in internode extension rate with a lag of less than 10 min. Following this, extension rate remained almost constant for at least 48 h. i.e. ‘re-etiolation’ was not noticed. The phytochorme controlling the growth processes was stable in the Pfr form. The growth rate of plants receiving a red light pulse, and the growth promotion caused by a far-red light pulse, increased with increasing fluence rate of the previous white light treatment. In far-red treated plants a first growth rate acceleration peaked at 20–30 min after the end of white light, followed by a transient deceleration which led to a growth rate minimum at 40–60 min, followed by a final growth rate recovery yielding a more-or-less steady elevated rate. Pulses establishing different Pfr/P modified the extent, but not the early kinetics, of the growth response. The relative promotion of growth caused by low Pfr/P was limited by darkness as follows: (a), The growth promotion caused by far-red directed to the internode alone was transient. (b), The promotion caused by a reduction of Pfr/P in the whole shoot persisted in darkness for at least 48 h and also persisted if, after a 3–9 h dark period, the plants were returned to continuous white light. In darkness, however, the magnitude of this growth rate promotion decreased with time, particularly when the previous white light fluence rate was low, or the pulse preceding darkness provided the lowest Pfr/P. (c), When compared over the same period in darkness, growth rate was higher in those seedlings in which Pfr/P was reduced during the continuous white light pretreatment than in those ones in which the Pfr/P was only reduced immediately before darkness. It is proposed that in the natural environment, red/far-red signals could be more effective when provided during daytime than at the end of the photoperiod, as both the background growth rate and the relative promotion caused by low Pfr/P are reduced by darkness.     

Light-quality effects on Arabidopsis development. Red, blue and far-red regulation of flowering and morphology

Arabidopsis thaliana (L.) Heynh. race Columbia plants were grown in red. blue, red + far-red, blue + far-red and various light mixtures of red + blue + far-red light under 14 h light/10 h dark photoperiods. Each single light source and light mixture maintained a constant irradiance (50 μmol m⁻² s⁻¹) and the mixtures of red + blue + far-red maintained a constant ratio of red/far-red light, but varied in the ratio of blue to red + far-red light. Depending on the method used for calculation, values of the fraction of phytochrome in the far-red absorbing form (P_fr/P_tot) for these light mixtures were either constant or decreased slightly with increasing percentage of blue light in the mixtures. Arabidopsis flowered early (20 days) in blue, blue + far-red and red + far-red light and late (55 days) in red light. In mixtures of red + blue + far-red light, each of which established a nearly constant P_fr/P_tot flowering was in direct relation to time and irradiance level of blue light. Leaf area and petiole length were also correlated with blue light irradiance levels.     

Response of stem explants to screening and explant source as a basis for methodical advancing of regeneration protocols for chrysanthemum

The effects of 2,4-dichlorophenoxyacetic acid (2,4-D) concentration, length of induction period and light quality on leaf regeneration of quince clone BA 29 were investigated. After 2, 4 or 6 days of induction with 2.5 mg l⁻¹ or 5.0 mg l⁻¹ 2,4-D, leaves were cultured under red, blue, red+blue, far-red+blue, white, far-red light or darkness conditions. Leaves thereby treated showed different responses, with respect to somatic embryogenesis, callus, red-nodular structures or roots. Callus production increased with increasing 2,4-D concentration and induction period, although it was not influenced by light quality; the only exception was far-red+blue light, which reduced callusing response. This result suggested involvement of the blue-absorbing photoreceptor system in the callus formation processes. A high regeneration of red-nodular structures with a meristematic appearance was also observed; from some histological characterizations, we presumed they were adventitious buds that were arrested at an early developmental stage. Red-nodular structures increased with decreasing 2,4-D concentration and induction period. In the regeneration of such structures, the blue-absorbing photoreceptor system appeared to have a negative effect but only at a low photoequilibrium value. In contrast, light quality which activated phytochrome induced an increment in regeneration, but the response did not vary for photoequilibrium values ranging from 0.43 to 0.86. For root regeneration, phytochrome seemed to be the only photoreceptor involved. This revised version was published online in June 2006 with corrections to the Cover Date.     

Photocontrol of anthocyanin formation in turnip seedlings

Summary As measured by in vivo spectrophotometry the phytochrome content in etiolated turnip seedlings was higher in cotyledons than in hypocotyls; in the latter, it is confined to the apical part. During early growth in darkness the amount increased in both tissues to a maximum, reached about 40 hours after sowing; the levels then gradually declined. Separation of seedlings into hypocotyl and cotyledons increased the rate of phytochrome loss in the former, but not in the latter.Following 5 minutes of red light P _frdecayed very rapidly in darkness; after 1.5 hours all of the phytochrome was present as P _r, which was presumably not converted initially. In continuous red light the total phytochrome was reduced to below the detection level within 3 hours. Seedling age markedly affected the loss of phytochrome following red light; more was destroyed in older than in younger hypocotyls and apparent new synthesis occurred only in young seedlings. The capacity to synthesise phytochrome differed in cotyledons and hypocotyl. In cotyledons, synthesis occurred following shots of red light varying from 10 seconds, to 6×I minute, but the amount of newly formed phytochrome was not related to the amount destroyed: after 5 hours of continuous red light no new synthesis occurred. In hypocotyls, the amount of phytochrome synthesised was related to the amount previously destroyed, and the phytochrome content after 24 hours of darkness was similar following all red light treatments of 1 minute or longer: new synthesis occurred following 5 hours of continuous red light.In far-red light phytochrome decayed very slowly, approaching the limit of detection after 48 hours. In cotyledons some loss was already observed after 5 hours of far-red and, in hypocotyls, after about 10 hours.These results are discussed in relation to the possible role of phytochrome as the pigment mediating anthocyanin synthesis in prolonged far-red light.