Mechanism of phytochrome action in the control of biosynthesis of anthocyanin in Brassica oleracea

-The synthesis of anthocyanin in red-cabbage is very sensitive to control by light, R/FR reversibility being effected by exposures of 5 min duration, The demonstration of this control does not depend upon a preceding irradiation of high-intensity light but depends upon the duration of incubation in darkness subsequent to irradiation. R/FR reversibility is well shown in seedlings kept in darkness for 48 hr after exposure but after 120 hr this reversibility is no longer evident. This is due to the fact that a further synthesis of anthocyanin occurs in unexposed seedlings and in FR and R/FR treated material in the period from 48 to 120 hr but does not occur in the R treatment after 48 hr. Reagents such as n-propanol which are believed to increase membrane permeability, greatly increase anthocyanin synthesis in dark grown material. n-PrOH also reverses the effect of 5 min FR irradiation but, by contrast with R light, does not promote PAL activity. It is concluded that the limitation to synthesis in material unexposed to light is substrate availability at the site of flavonoid biosynthesis, rather than the level of PAL activity. The evidence presented supports the hypothesis that R/FR reversible phytochrome action involves the control of the passage of substrate through a membrane to the site of anthocyanin biosynthesis.     

Plastid 3-hydroxy-3-methylglutaryl coenzyme A reductase has distinctive kinetic and regulatory features: Properties of the enzyme and positive phytochrome control of activity in pea seedlings

Plastid 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase (mevalonate:NADP oxidoreductase [acylating CoA] EC 1.1.1.34) differs from the cytosolic (microsomal) reductase in pH optimum and apparent K_m for RS-HMG-CoA. Values for the plastid and cytosolic enzyme (brackets) are: pH optimum 7.9 (6.9); apparent K_mRS-HMG-CoA, 0.77 μm (160 μm). Hence the plastid and cytosolic enzymes appear to be different species and not simply compartmented forms of the same protein. The plastid reductase is membrane bound, optimally active only in the presence of dithiothreitol, and specifically requires NADPH; in these respects it is similar to the cytosolic enzyme. In dark-grown seedlings irradiated with red light plastid reductase activity increases to 139% of controls after 20 min, approximately double after 1.75 h, and subsequently declines to a new steady state higher than controls. Far-red reversal studies indicate phytochrome (Pfr) mediation. Reversal can only be demonstrated with very brief (1.5 min) red irradiation followed immediately by far red. It is concluded that Pfr does not act by binding to the enzyme, but that the regulatory mechanism is closely linked to the primary action of Pfr. The rapid Pfr stimulation indicates that this is an early event in the phytochrome control of chloroplast development. The response time and light effects on plastid isoprenoids (photosynthetic and hormonal) also suggest that the regulation of this enzyme is associated with the coordinate control of chloroplast and leaf development by phytochrome. The present positive Pfr control of the plastid reductase contrasts with the previously reported negative Pfr control of the cytosolic reductase.     

Red light-induced accumulation of ubiquitin-phytochrome conjugates in both monocots and dicots

Phytochrome is rapidly degraded in vivo after photoconversion from the stable red-absorbing (Pr) form to the far red-absorbing (Pfr) form. Previously, we have shown in etiolated oat seedlings that ubiquitin-phytochrome conjugates (Ub-P) appear after Pfr formation suggesting that oat phytochrome is rapidly degraded by a ubiquitin-dependent proteolytic pathway. Here, we extend this observation to etiolated tissue from other monocotyledonous (corn [Zea mays. (L.)] and rye [Secale cereale (L.)] and dicotyledonous species (pea [Pisum sativum (L,)] and zucchini squash [Cucurbita pepo (L.)]). Following Pfr formation by red light, all four species synthesized a heterogeneous series of Ub-P that appeared and disappeared concomitant with the degradation of the chromoprotein. When Pfr was photoconverted back to Pr by a far-red light pulse, degradation of phytochrome ceased and the levels of Ub-P concomitantly dropped. In pea and zucchini squash, loss of Ub-P after photoconversion of Pfr back to Pr was rapid, occurring with a half-life of approximately 5 to 10 minutes. These data indicate that the accumulation of Ub-P after Pfr formation is a general phenomenon in etiolated seedlings of higher plants and further support the hypothesis that plants degrade Pfr via Ub-P intermediates.     

In Vivo Properties of Membrane-bound Phytochrome

After a 3-minute irradiation with red light, which saturates the phototransformation from the red light-absorbing form of phytochrome to the far red light absorbing form of phytochrome, about 40% of the phytochrome extractable from hooks of etiolated squash seedlings (Cucurbita pepo L. cv. Black Beauty) can be pelleted as Pfr at 17,000g after 30 minutes. Dark controls yield only 2 to 4% pelletable phytochrome in the form Pr. If a dark period intervenes between red irradiation and extraction, the bound Pfr gradually loses its photoreversibility. The time course for this destruction parallels the time course for phytochrome destruction in vivo following saturating red irradiation. The soluble fraction of phytochrome remains constant. These results suggest that in squash seedlings phytochrome destruction is related exclusively to the fraction which becomes membrane-bound. The induction of phytochrome binding by red light is not completely reversible by far red. In plants given saturating red followed immediately by saturating far red light, 12% of the phytochrome is found in the bound fraction as Pr if the phytochrome extraction is immediate. If a dark period intervenes between red-far red treatment and extraction, the bound phytochrome is released within 2 hours. A model of the binding properties of phytochrome, based on molecular interaction at the membrane is proposed, and possible consequences for the mechanism of action of phytochrome are discussed.     

Prevention of Action of Far-Red-Absorbing Phytochrome in Rumex crispus L. Seeds by Ethanol

Phytochrome-enhanced germination of curled dock (Rumex crispus L.) seeds is further stimulated by pretreatments in solutions of 0.5 to 2 molar methanol and 0.03 to ≥ 0.3 molar 2-propanol during a 2-day 20°C imbibition. Similar pretreatments in 0.1 molar ethanol, acetaldehyde, and n-propanol inhibit phytochrome-enhanced germination. If exposure to ethanol is delayed until 16 hours after a red irradiation, seeds escape the ethanol inhibition indicating a mechanism other than toxicity. The rate of escape from ethanol inhibition roughly parallels the escape from phytochrome control in seeds held in water only, indicating possible ethanol effects on phytochrome. It was found that ethanol pretreatment prevents the far-red absorbing form of phytochrome (Pfr) from acting but does not accelerate dark decay or prevent transformation. Ethanol inhibition may be prevented if ethanol pretreatment is at 10°C instead of 20°C, or may be overcome by transferring ethanol-pretreated seeds to 10°C in water. Similarly, ethanol inhibition can be overcome by a 2-hour 40°C temperature shift concluding the pretreatment. It is proposed that the ethanol causes perturbations at a membrane which prevent Pfr from acting.     

Analysis of the Effect of Light and Temperature on the Fluence Response Curves for Germination of Rumex obtusifolius

Both red light (10 minutes) and 35°C treatment (60 minutes) stimulate the germination of seeds of Rumex obtusifolius otherwise maintained in darkness at 25°C. Fluence response curves were determined for the effect of red light to stimulate germination of seeds with and without 35°C treatment. The endogenous far-red absorbing form (Pfr) level in the seeds was determined using short saturating fluences of wavelengths of light which maintain different proportions of phytochrome as Pfr at equilibrium. In the seed batches investigated, the endogenous Pfr level was found to be 4% or less of the total phytochrome. High dark germination after 35°C treatment does not result from an increase in sensitivity of the whole population to Pfr. Calculated fluence response curves for germination which best fit the experimental data suggest that seeds germinate in darkness after 35°C treatment because of a nonphytochrome-related process (overriding factor).     

Phytochrome action on chlorophyll synthesis-a study of the escape from photoreversibility

A brief red light pretreatment (pulse), operating through phytochrome, stimulates the synthesis of chlorophyll a and b in Sorghum vulgare shoots that are placed in continuous saturating white light. The red light effect is fully reversible by a far-red (756 nanometers) light pulse for 45 minutes. Thereafter, escape from reversibility is fast, being completed within 2 hours. It is shown here that physiologically active phytochrome (Pfr) is required continuously during these first 45 minutes if the onset of the loss of photoreversibility is to begin 45 minutes after the red light treatment. Thus, the initial action of Pfr consists of two distinct processes: the first process is to overcome the lag prior to escape from photoreversibility; the second process is the actual stimulation of chlorophyll synthesis by Pfr. The duration of the lag prior to escape from photoreversibility depends on the level of Pfr established by the light pulse. The duration increases with increasing Pfr levels from nondetectable to 45 minutes. Above approximately 15% Pfr (Pfr/P_lot ≈ 0.15), the duration of the lag prior to escape from photoreversibility remains constant at 45 minutes.     

Amplification of phytochrome induced morphogenesis in plants by the cryptic red light signal (CRS)

The regulation of endogenous levels of ascorbic acid in soybean by far-red absorbing form of phytochrome (Pfr) and by cryptic red light signal (CRS) was studied. Cryptic red light signal is produced by red light pre-irradiation of a photoreceptor other than far-red absorbing form of phytochrome (Pfr) and CRS amplifies the action of phytochrome. The endogenous level of ascorbic acid levels enhanced by phytochrome was amplified by CRS. The lifetime of CRS was from 0 to 2 h and the peak of enhancement of ascorbic acid due to CRS was between 16 to 24 h of dark incubation after the end of the treatment. CRS was found to be ineffective on UV-B enhanced endogenous levels of ascorbic acid.Key words: ascorbic acid, cryptic red light signal, glycine max, phytochrome, ultraviolet-BThe phytochrome mediated morphogenesis involves the conversion of Pr [red absorbing form] to Pfr [far-red absorbing form] and the magnitude of the response is dependent on Pfr/P tot ratio established at the end of the irradiation.¹ In broom Sorghum anthocyanin synthesis induced by red light [R₁] is reversible with far-red light. But a second red pulse [R₂] given after the reversal resulted in increased anthocyanin production compared to the first pulse [R₁]. When the red pulse was repeatedly given after every reversal with far-red, the anthocyanin production increased proportionately to the number of previously given pulses.² Thus red pre-treatment induced a change in the cellular physiological state or change in content of a relevant substance[s] which is designated as Cryptic Red Light Signal [CRS] associated with red signal transduction.² CRS was first characterized in detail in Broom Sorghum as Pfr amplifying signal produced by red pre-irradiation. CRS is inactive in the absence of Pfr but enhances the action of Pfr. CRS escapes reversal when the plants are exposed to far-red and is probably produced by a different species of phytochrome, distinct from the conventional reversible phytochrome.³We have investigated whether CRS influences other phytochrome regulated processes in plants in addition to anthocyanin synthesis. We chose another process, the synthesis of endogenous ascorbic acid, which is also regulated by conventional phytochrome.⁴ In soybean, the endogenous level of ascorbic acid is enhanced by conventional far-red reversible form of phytochrome. In addition, an independent UV-B photoreceptor [non reversible with far-red light] also enhances the endogenous synthesis of ascorbic acid in soybean. By using repeated pulses of red light, we have demonstrated that the Cryptic Red Signal is operative in soybean also and it amplifies the red light induced enhancement in the level of ascorbic acid. That CRS is active only in the presence of Pfr is demonstrated by the fact that pre-irradiation with red light is ineffective in amplifying UV-B induced enhancement of ascorbic acid levels. A similar observation on UV-B induced anthocyanin synthesis has been made in Broom Sorghum.² A separate UV-B photoreceptor independent of phytochrome operates in the plants.⁵ Although CRS is presumably produced by pre-irradiation with red light, it does not enhance UV-B induced anthocyanin synthesis or ascorbic acid synthesis in the absence of formation of Pfr by the second red pulse.The life-time of CRS was determined as 6 h in 20°C and 3 h in 24°C grown seedlings of Broom Sorghum with reference to anthocyanin synthesis.² The life-time of CRS determined in soybean seedlings grown at 25°C was upto 1 h.⁶ Since growing seedlings at a low temperature enhanced the effectiveness of CRS in Broom Sorghum, it was concluded that low temperature may either extend the lifetime of CRS or generate higher amount of CRS.² Although the exact nature of CRS is yet to be analyzed, work in our laboratory has established the universal nature of this signal and evidences have been obtained for CRS effect in promoting red light induced hypocotyls inhibition in Cucumber seedlings and also red light induced synthesis of betacyanins in Amaranthus seedlings (submitted for publication).     

Phytochrome Action during Prechilling Induced Germination of Betula papyrifera Marsh

Seeds of paper birch (Betula papyrifera Marsh.) were induced to germinate by prechilling at 3 C or by red light. The light requirement was mediated by phytochrome and the action of phytochrome during prechilling was investigated. Red irradiation (R) prior to prechilling markedly enhanced the effectiveness of the prechilling treatment in inducing subsequent germination at 18 C. Reversal of this enhancement by far-red irradiation (FR) was more effective when FR was supplied after a 1-week prechill treatment than after a 2-week treatment. The R enhancement effect exhibited a sharp drop as prechilling temperature was increased from 5 to 7 C. This decline is consistent with a membrane phase transition at about 7 C where Pfr action is diminished by a loss in sensitivity of its receptor sites. Although phytochrome action was observed during prechilling treatments, the seeds failed to germinate at prechilling temperatures. Therefore, it was concluded that while potentiation of germination by Pfr occurred during prechilling, some other reaction(s) leading to radicle protrusion requires higher temperatures. In one seed source loss of germination potential was observed with protracted storage at 3 C. This was prevented by R supplied during the prechilling treatment. Taken collectively the data suggest that action of phytochrome during prechilling is accentuated in these seeds by two factors: (a) an increase in the sensitivity (or number) of Pfr receptor sites; and (b) preservation of Pfr by deferment of thermal reversion.     

Cryptochrome, Phytochrome, and the Photoregulation of Anthocyanin Production under Blue Light

The principle of equivalent light action predicts that two light treatments (wavelengths ^λ₁ and λ₂) producing the same Pfr/P ratio (_λ1 = _λ2) and the same rate of phytochrome photoconversion (k_λ1 = k_λ2) are perceived by phytochrome as being the same and should produce the same effect. The results of experiments based on the principle of equivalent light action indicate that cryptochrome is involved in the photoregulation of anthocyanin production elicited by blue light in tomato seedlings. This was also the case for one strain of cabbage seedlings. For another strain of cabbage seedlings, the results suggest that cryptochrome is either not involved or that the state of phytochrome is the principal limiting factor.     

Changes in Nucleic Acids in Phytochrome-dependent Elongation of the Alaska Pea Epicotyl

Red light, which produces the physiologically active form of phytochrome (Pfr), inhibited epicotyl elongation in intact dark-grown Alaska pea seedlings. This red light response was detectable 3 hours after the light treatment and became pronounced after 5 hours. The growth inhibition was completely reversed by far red light applied immediately after the red or by pretreatment of the seedlings with the plant hormone gibberellin A₃.     

Discrimination between the red- and far-red-absorbing forms of phytochrome from Avena sativa L. by monoclonal antibodies

A set of rat monoclonal antibodies (ARC MAC 48 to 52 and 54 to 56), raised to phytochrome from dark-grown seedlings of Avena sativa L. was tested for the ability to discriminate between the red-absorbing (Pr) and far-red-absorbing (Pfr) forms of phytochrome by indirect enzyme-linked immunosorbent assay. MAC 50 bound more strongly to Pfr and MAC 49 and 52 showed preferential binding to Pr from extracts of dark-grown Avena seedlings; MAC 50 also bound more strongly to Pfr from brushite-purified phytochrome. The remainder of the monoclonal antibodies and a rabbit polyclonal antiphytochrome preparation did not discriminate between Pr and Pfr. The results provide evidence for conformational changes in defined regions of the phytochrome apoprotein upon photoconversion.Abbreviations ELISA enzyme-linked immunosorbent assay - FR far-red light - McAb monoclonal antibody(ies) - PBS phosphate-buffered saline - Pfr far-red-absorbing form of phytochrome - Pr red-absorbing form of phytochrome - R red light - PMSF phenylmethylsulphonylfluoride     

Intracellular localisation of phytochrome in oat coleoptiles by electron microscopy

The intracellular localisation of phytochrome in oat (Avena sativa L. cv. Garry Oat) coleoptiles was analysed by electron microscopy. Serial ultrathin sections of resin-embedded material were indirectly immunolabeled with polyclonal antibodies against phytochrome together with a gold-coupled second antibody. The limits of detectability of sequestered areas of phytochrome (SAPs) were analysed as a function of light pretreatments and amounts of the far-red absorbing form of phytochrome (Pfr) established. In 5-d-old dark-grownAvena coleoptiles SAPs were not detectable if less than 13 units of Pfr — compared with 100 units total phytochrome of 5-d-old dark-grown seedlings — were established by a red light pulse. In other sets of experiments, seedlings were preirradiated either with a non-saturating red light pulse to allow destruction to occur or with a saturating red followed by a far-red light pulse to induce first SAP formation and then its disaggregation. These preirradiations resulted in an increase of the limit of detectability of SAP formation after a second red light pulse to 38–41 and 19–23 units Pfr, respectively. We conclude that with respect to Pfr-induced SAP formation an adaptation process exists and that our data indicate that SAP formation is not a simple self-aggregation of newly formed Pfr.Abbreviations FR far-red light - Pfr, Pr far-red-absorbing and red-absorbing forms of phytochrome, respectively - Plot total phytochrome (Pfr + Pr) - R red light - SAP sequestered areas of phytochrome This work was supported by Deutsche Forschungsgemeinschaft (SFB 206). The competent technical assistance of Karin Fischer is gratefully acknowledged.     

Model for variable light sensitivity in imbibed dark-dormant seeds

The level of light-induced germination of the seed of common purslane (Portulaca oleracea L.) and curly dock (Rumex crispus L.) changes with dark incubation time prior to brief, low energy, red light treatment. The rate at which phytochrome—far red-absorbing form (Pfr) acts in the light-induced population of seeds was measured by quantitating per cent reversals of the red light effect with saturating far red light exposures at successive times after the red light exposure. A linear positive correlation was found between this rate and the final germination level. These results are compatible with a model involving changing levels, during dark incubation, of a component with which Pfr interacts. In this model, germination is initiated after attainment of a certain level of interaction between Pfr and this component. These findings also support the view that the Pfr to Pr decay rate constant and total phytochrome level are stable during dark incubation.     

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.     

Is the far-red-absorbing form of Avena phytochrome A that is present at the end of the day able to sustain stem-growth inhibition during the night in transgenic tobacco and tomato seedlings?

Avena phytochrome A (phyA) overexpressed in tobacco (Nicotiana tabacum L.) and tomato (Lycopersicon sculentum Mill) was functionally characterised by comparing wild-type (WT) and transgenic seedlings. Different proportions of phytochrome in its far-red-absorbing form (Pfr/P) were provided by end-of-day (EOD) light pulses. Stem-length responses occurred largely in the range of low Pfr/P (3–61%) for WT seedlings and in the range of high Pfr/P (61–87%) for transgenic seedlings. A similar shift was observed when the photoperiod was interrupted by short light pulses providing different Pfr/P ratios and followed by 1 h dark incubation. In other experiments, Avena phyA was allowed to re-accumulate in darkness and subsequently phototransformed to Pfr but no extra inhibition of stem extension growth was observed. In transgenic tomato seedlings the response to EOD far-red light was faster and the response to a far-red light pulse delayed into darkness was larger than in the WT. Avena phyA Pfr remaining at the end of the photoperiod appears intrinsically unable to sustain growth inhibition in subsequent darkness. Avena phyA modifies the sensitivity and the kinetics of EOD responses mediated by native phytochrome.Abbreviations EOD end-of-day - FR far-red light - Pfr/P pro-portion of phytochrome in its FR-absorbing form - phyA phyto-chrome A - phyB phytochrome B - R red light - RFR R to FR ratio - WT wild type We thank Dr Brian Thomas for providing the antibodies used in this work, and Federico Guerendiain for his excellent technical assistance. This work was financially supported by grants UBA AG 040 and Fundacion Antorchas A-12830/1-19 (both to J.J.C.), PID-CONICET (to R.A.S. and J.J.C.), United States Department of Energy DE-FG02-88ER13968 (to R.D.V.).     

The influence of light quality on the phytochrome content of light grown Sinapis alba L. and Phaseolus aureus Roxb.

The effect on the phytochrome system of light regimes establishing a range of photoequilibria was studied in two light grown dicotyledonous plants, both of which were treated with the herbicide SAN 9789 to prevent chlorophyll accumulation. In Sinapis alba L. cotyledons the results are comparable with phytochrome behaviour in etiolated mustard seedlings; the level of Pfr becomes independent of wave-length whereas the total phytochrome level is wave-length dependent. Contrasting properties are exhibited in Phaseolus aureus Roxb. leaves in which total phytochrome is unaffected by light quality; consequently the Pfr level is dependent on wavelength. Nevertheless, the amount of phytochrome in mung leaves increased after transfer to darkness suggesting that light still has a profound influence on the phytochrome system, even though light quality during the light period and prior to darkness does not.Abbreviations FR far-red light - WL white light - PAR photosynthetically active radiation - Pfr far-red light absorbing form of phytochrome - Pr red light absorbing form of phytochrome - Ptot total phytochrome level (=Pr+Pfr) - Pfr/Pfr+Pr - SAN 9789 4-chloro-5-(methylamino) 2(,, trifluoro-m tolyl)-3(2H)-pyridazinone     

Avena phytochrome a overexpressed in transgenic tobacco seedlings differentially affects red/far-red reversible and very-low-fluence responses (cotyledon unfolding) during de-etiolation

Etiolated seedlings of tobacco (Nicotiana tabacum L.) were exposed to single light pulses predicted to establish different proportions of phytochrome in its far-red absorbing form (Pfr/P). The angle between the cotyledons was compared in wild-type and transgenic seedling overexpressing Avena phytochrome A over the range of both very low-fluence responses (VLFR) and low-fluence responses (LFR). The unfolding of the cotyledons increased linearly for 24 h after the light pulse. At this time the Pfr/P-response curve showed two linear segments. The segment below a calculated Pfr/P = 3% (i.e. VLFR) was steeper than the segment above 3% (i.e. LFR). In the VLFR range the slope was almost threefold higher in transgenic than wild-type seedlings. However, in the LFR range the difference was less than 50%. From these data we propose that Avena phytochrome A makes a higher contribution to VLFR than LFR in etiolated tobacco seedlings.Abbreviations FR far-red light - LFR low-fluence response - Pfr/P proportion of phytochrome (P) in its FR-absorbing form (Pfr) - R red light - VLFR very low-fluence response Financial support was provided by the University of Buenos Aires and Fundación Antorchas (Argentina) to J.J.C., CONICET (Argentina) to R.A.S. and the U.S. Department of Energy (DE-FG02-88ER13968) to R.D.V.     

EFFECTS OF TEMPERATURE AND AERATION ON PHYTOCHROME TRANSFORMATIONS IN PASTINACA SATIVA ROOT TISSUE

Phytochrome reversion from the Pfr form to the Pr form in Pastinaca sativa L. tissue occurs very rapidly during the first 1½ hr after exposure to red light and then more slowly; some Pfr is still present after 12 hr at 26 C. Phytochrome destruction, on the other hand, is initially very slow and does not become evident until after the period of rapid reversion. The rate of reversion is reduced by low temperatures but not by low levels of oxygen. Phytochrome destruction in parsnip tissue briefly exposed to red light is also unaffected by low levels of oxygen, suggesting that it may differ in mechanism from destruction in etiolated seedlings. However, reduced oxygen levels inhibit phytochrome loss in tissues held in darkness. Phytochrome in cauliflower tissue proved to be fully light-stable, confirming earlier observations.     

Light quantity and quality interactions in the control of elongation growth in light-grown Chenopodium rubrum L. seedlings

The spectral control of hypocotyl elongation in light-grown Chenopodium rubrum L. seedlings has been studied. The results showed that although the seedlings responded to changes in the quantity of combined red and far-red radiation, they were also very sensitive to changes in the quantity of blue radiation reaching the plant. Altering the proportion of red: far-red radiation in broad waveband white light caused marked differences in hypocotyl extension. Comparison of the responses of green and chlorophyll-free seedlings indicated no qualitative difference in the response to any of the light sources used, although photosynthetically incompetent plants were more sensitive to all wavelengths. Blue light was found to act primarily of a photoreceptor which is different from phytochrome. It is concluded that hypocotyl extension rate in vegetation shade is photoregulated by the quantity of blue light and the proportion of red: far-red radiation. In neutral shade, such as that caused by stones or overlying soil, hypocotyl extension appears to be regulated primarily by the quantity of light in the blue waveband and secondarily by the quantity of light in the red and far-red wavebands.Abbreviations B blue - FR far-red - k ₁, k ₂ rate constants for photoconverison of Pr to Pfr and Pfr to Pr, respective - k ₁/k ₁ +k ₂= phytochrome photoequilibrium - k ₁ +k ₂= phytochrome cycling rate - Pr=R absorbing form of phytochrome - Pfr=FR absorbing form of phytochrome - P_tot Pr+Pfr - PAR photosynthetically active radiation = 400–700 nm - R red - WL white light