Etude du phytochrome detectable,in vivo dans les graines de Cucurbita pepo L. au cours des differentes phases de la germination

Summary In dry gourd seeds all the phytochrome is in the P_fr form. The increase of phytochrome content from the beginning of hydration involves two phases, A and B, in the embryonic axis as well as in the cotyledons. Cycloheximide does not prevent the appearance of P_r during phase A. We assume that P_r is gradually released from an inactive complex. On the other hand phase B is inhibited by cycloheximide; this could mean that a de novo synthesis of P_r occurs.Some experiments indicate that the phytochrome which is localized in the embryonic axis may be involved only in the germinating process.The phytochrome which is synthesized during phase B disappears when the seeds are irradiated with red light, while the original phytochrome does not.According to our data it seems necessary to lay down a new and precise definition of the germination process.     

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.     

Nutrients-mediated shift in temporal expression of phytochrome controlled β-amylase synthesis in mustard (Sinapis alba L.) cotyledons

Abstract. In cotyledons of mustard ( Sinapis alba L.) seedlings grown with distilled water (DW) phytochrome controlled increase in β-amylase (E.C. 3.2.1.2) level takes place at about 42 h after sowing (starting point), while the photoresponse escapes from photoreversibility at 30 h after sowing. The temporal onset of starting point is presumed to be determined by innate process of developmental homeostasis, which is not amenable to influence of environmental factors such as light and nutrients. However, the temporal appearance of onset of phytochrome controlled increase in β-amylase level (starting point) in seedlings grown with Hoagland's nutrient solution (HS) is delayed by 9 h as compared to DW-grown seedlings. Concomitantly, the temporal appearance of the loss of photoreversibility of phytochrome mediated increase in β-amylase level (coupling point) is also delayed by 9 h in HS-grown seedlings. HS does not influence the primary action of phytochrome, the lifetime of components involved in signal chain of above photoresponse and the turnover of β-amylase enzyme. These results indicate that HS-induced temporal shift in onset of starting point of above photoresponse is caused by interaction of nutrients with the process of developmental homeostasis.     

Rapid activation by phytochrome of nitrate reductase in the cotyledons of Sinapis alba

Summary Nitrate reductase in the cotyledons of etiolated seedlings of Sinapis alba L. responds rapidly to the addition of nitrate. The response is inhibited by cycloheximide at low concentrations. The enzyme is also under phytochrome control. Five minutes of red light irradiation leads instantaneously to a 45% increase in enzyme activity. Increases in activity, linear with respect to time and with no lag phases are promoted by continuous far-red or blue irradiation. These increases are insensitive to cycloheximide. Thus, light and nitrate act through different mechanisms in controlling nitrate reductase activity and phytochrome does not act via controlling the rate of synthesis of the enzyme.Abbreviation cot pr pair of cotyledons     

Studies on Greening of Etiolated Seedlings II. Leaf Greening by Phytochrome Action in the Embryonic Axis

We could demonstrate that greening of primary bean leaves in etiolated seedlings of Phaseolus vulgaris cv. Limburg can be controlled by a selective light-pretreatment of the embryonic axis. This light-induced interorgan synergism proved to be a phytochrome-mediated process. The red/farred photoreversible effect on the embryonic axis seems to be primarily linked to changes in the energy metabolism of the primary leaves. Phototransformation of the protochlorophyll present and pigment synthesis are very dependent upon an adequate supply of biochemical energy. When the embryonic axis is selectively pre-exposed to red light for a short time, respiration is markedly enhanced in the leaves and photosynthesis starts immediately upon illumination of the etiolated leaves after an incubation period of optimal length in the dark. The stimulatory effect of the red pretreatment on leaf respiration and photosynthetic capacity could be abolished to the level of the dark controls by a subsequent far-red irradiation on the embryonic axis. It is therefore postulated that phytochrome plays a regulatory role in interorgan cooperation. The metabolic changes involved in photomorphogenesis of etiolated seedlings are closely related to changes in energy production. Our data indicate that the primary act of phytochrome becomes operative at the biochemical level by its directional influence on the energy balance of the cell and coordinates the use of metabolic energy within a tissue and between organs.     

Photocontrol of the synthesis of chlorophyll a and phycocyanin in the cyanobacterium Calothrix crustacea Schousboe]

Chlorophyll a and phycocyanin synthesis in the cyanobacterium Calothrix crustacea Schousboe (ecophene Rivularia bullata) have been studied in white light after the application of red and green light pulses. The light quality produces a complementary pattern in the pigment synthesis. Chlorophyll synthesis is stimulated by red light pulses whereas phycocyanin synthesis is by green light pulses. Because the effect of red light on chlorophyll synthesis shows some far-red photoreversibility, the action of phytochrome is proposed. The green light effect on phycocyanin synthesis is only partially reversed by far-red light. This reversion is lost after incubation in white light for two hours. The effect of green light on phycocyanin synthesis could not only be due to phytochrome since theoretically in green light the level of the active form of phytochrome is lower than in red light. Thus, the action of a specific green light photoreceptor is proposed.     

Phytochrome-Mediated Increase in Glutamine Synthetase Activity in Photosensitive New York Lettuce Seeds

Red light increased glutamine synthetase (GS) activity in NewYork lettuce seeds before the initiation of axes elongation.The increase in GS activity was shown to be mediated by phytochrome.The escape reaction of the red-light effect on GS activity proceededfor several hours at 25°C, and roughly fitted that on thegermination. The effect of red light on the increase in GS activitywas inhibited completely by cycloheximide, but not at all byactinomycin D. The increased GS activity in the embryonic axesis discussed in relation to the promotive effect of red lighton lettuce-seed germination. (Received May 26, 1983; Accepted September 14, 1983)     

An Analysis of Phytochrome-mediated Anthocyanin Synthesis

Phytochrome (far red form) alone can mediate anthocyanin synthesis in the mustard seedling (Sinapis alba L.). Complete photoreversibility and reciprocity, for both red and far red light exposures over a period of at least 5 minutes, demonstrate this phytochrome involvement.     

CELL ELONGATION IN THE CULTURED EMBRYONIC CHICK LENS EPITHELIUM WITH AND WITHOUT PROTEIN SYNTHESIS : Involvement of Microtubules

Previous studies have shown that cells in the 6-day old embryonic chick lens epithelium elongate in tissue culture. In the present study, the time course of elongation during the 1st day of cultivation has been examined histologically. Cultured epithelia were also treated with cycloheximide or colchicine in order to determine if cell elongation depends on new protein synthesis and on the utilization of microtubules, respectively. In the first 5 hr of culture, the mean cell length increased from 11 µ to 21 µ. Subsequently, elongation was slower; the mean cell length was 28 µ after 24 hr in culture. Continuous exposure to cycloheximide did not inhibit the initial doubling of cell length, but did prevent further elongation. By contrast, colchicine inhibited elongation almost immediately. When added after the cell length had doubled, cycloheximide and colchicine each inhibited further elongation; the treated cells remained columnar. Radioautographic and electrophoretic tests showed that protein synthesis was not appreciably affected by colchicine, but was suppressed by cycloheximide. Electron microscopic examination revealed that microtubules oriented along surface membranes were present in epithelia cultured with serum alone and with cycloheximide, but not in those incubated with colchicine. These results indicate that the early stages of cell elongation in the cultured lens epithelium require an initial assembly and organization of preexisting microtubular elements and that continued elongation depends, in addition, on the de novo synthesis of protein, possibly microtubule protein.     

Spore germination and phytochrome biosynthesis in the fern Lygodium japonicum as affected by gabaculine and cycloheximide

We investigated whether the gradual increase in phytochrome content in the fern Lygodium japonicum (Thunb.) Sw. during dark imbibition results from hydration or from biosynthesis of phytochrome. Addition of gabaculine or cycloheximide to the culture medium caused inhibitions of both red light-induced spore germination and of the appearance of phytochrome in the spores. Fifty percent inhibition of both red light-induced germination and of the appearance of phytochrome in the spores occurred at ca 10⁻7 M cycloheximide. Red light-induced germination and phytochrome appearance were markedly inhibited by 10⁻4 M and completely by 10⁻3 M gabaculine, but germination induced by gibberellic acid was unaffected. Phytochrome was not detected in spores after forced hydration. These results suggest that the increase in phytochrome during imbibition was mainly due to de novo synthesis of the phytochrome apoprotein and to synthesis of the chromophore and/or proteins required for phytochrome formation, rather than to hydration of preexisting phytochrome molecules.     

Timing of the Auxin Response in Coleoptiles and Its Implications Regarding Auxin Action

The timing of the auxin response was followed in oat and corn coleoptile tissue by a sensitive optical method in which the elongation of about a dozen coleoptile segments was recorded automatically. The response possesses a latent period of about 10 min at 23°C, which is extended by low concentrations of KCN or by reducing the temperature, but is not extended by pretreatments with actinomycin D, puromycin, or cycloheximide at concentrations that partially inhibit the elongation response. Analysis of the data indicates that auxin probably does not act on the elongation of these tissues by promoting the synthesis of informational RNA or of enzymatic protein. Not excluded is the possibility that auxin acts at the translational level to induce synthesis of a structural protein, such as cell wall protein or membrane protein. While the data do not provide direct support for this hypothesis, the speed with which cycloheximide inhibits elongation suggests that continual protein synthesis may be important in the mechanism of cell wall expansion.     

Action spectrum and characteristics of the light activated disappearance of phytochrome in oat seedlings

The action spectrum for the light-activated destruction of phytochrome in etiolated Avena seedlings has been determined. There are 2 broad maxima, one between 380 and 440 mμ, the other between 600 and 700 mμ. peaking at about 660 mμ. On an incident energy basis, the red region of the spectrum is more efficient than the blue by about one order of magnitude in activating phytochrome disappearance. Both the red absorbing as well as the far-red absorbing forms of phytochrome are destroyed after exposure of Avena seedling to either red or blue light.

From the action spectrum and photoreversibility of pigment loss, we conclude that phytochrome acts as a photoreceptor for the photoactivation of its metabolically-based destruction. We suggest that another pigment might also be associated with the disappearance of phytochrome in oat seedlings exposed to blue light.

     

Aphototropic mutants of the moss Ceratodon purpureus with spectrally normal and with spectrally dysfunctional phytochrome

Following UV mutagenesis of protonemal tissue of the moss Ceratodon purpureus we have isolated different aphototropic mutant lines that can be divided into two distinct classes. One class, represented by the line ptr1, shows characteristic features of phytochrome chromophore deficiency. ptrl shows negligible photoreversibility (<5% of wild type), whereas immunoblots show normal apoprotein levels. The aphototropic phenotype could be partially restored with biliverdin, a precursor of the phytochrome chromophore. It was found that, whereas in wild type formation of Pfr leads to suppression of gravitropism, there is no such suppression ptrl. In addition, ptr1 shows lower chlorophyll levels than the wild type. These findings indicate that, as expected for a chromophore-deficient mutant, multiple phytochrome effects are lost. The other class of mutants, represented by the line ptr103, shows more specific effects. In this mutant, only phototropism is affected. Suppression of gravitropism, the content of chlorophyll and photoreversibility of phytochrome were similar to those of the wild type.     

Biochemical and spectroscopic characterization of the bacterial phytochrome of Pseudomonas aeruginosa

Phytochromes are photochromic biliproteins found in plants as well as in some cyanotrophic, photoautotrophic and heterotrophic bacteria. In many bacteria, their function is largely unknown. Here we describe the biochemical and spectroscopic characterization of recombinant bacterial phytochrome from the opportunistic pathogen Pseudomonas aeruginosa (PaBphP). The recombinant protein displays all the characteristic features of a bonafide phytochrome. In contrast with cyanobacteria and plants, the chromophore of this bacterial phytochrome is biliverdin IXalpha, which is produced by the heme oxygenase BphO in P. aeruginosa. This chromophore was shown to be covalently attached via its A-ring endo-vinyl group to a cysteine residue outside the defined bilin lyase domain of plant and cyanobacterial phytochromes. Site-directed mutagenesis identified Cys12 and His247 as being important for chromophore binding and photoreversibility, respectively. PaBphP is synthesized in the dark in the red-light-absorbing Pr form and immediately converted into a far-red-light-absorbing Pfr-enriched form. It shows the characteristic red/far-red-light-induced photoreversibility of phytochromes. A chromophore analog that lacks the C15/16 double bond was used to show that this photoreversibility is due to a 15Z/15E isomerization of the biliverdin chromophore. Autophosphorylation of PaBphP was demonstrated, confirming its role as a sensor kinase of a bacterial two-component signaling system.     

Cycloheximide effect on DNA degradation and delta-crystallin synthesis in terminally differentiating lens cells

Low concentrations of a protein synthesis inhibitor, cycloheximide, were added throughout the process of in vitro differentiation of 11-day old embryonic chick lens cells. We found with low concentrations of cycloheximide (0.01 to 0.03 microgram/ml, 3 days of culture), that there was an almost complete delay of DNA degradation as observed on alkaline sucrose gradient. Identical concentrations and exposure time had no blocking effect on increased delta-crystallin synthesis as detected by immunoprecipitation and electrophoresis. Higher concentrations of cycloheximide (0.1 to 1 microgram/ml) showed a marked effect on DNA size and a net inhibition on delta-crystallin synthesis. Thus a selective effect of low doses of cycloheximide was observed on terminal differentiation suggesting that there was not a relationship between DNA degradation and delta-crystallin synthesis in these short term experiments. The investigations of minor proteins could be of interest as they may have a crucial role in intact nuclei cataracts.     

Phytochrome Activation of K+ Channels and Chloroplast Rotation in Mougeotia: the Escape Times

Red light mediates chloroplast movement and increased activityof calcium-activated potassium channels on the plasma membraneof the alga Mougeotia sp. (UTEX LB 734). When activation ismediated by phytochrome, a far-red light irradiation given sometime after the red light irradiation will reverse the effectof the red light, due to phytochrome photoreversibility. Wecharacterized the escape times (time required for loss of photoreversibility)for these two processes to compare the transduction pathwaysinvolved in chloroplast rotation and channel activation. Theescape time for chloroplast rotation was 2.5 min after red lightirradiation (red and far-red light irradiations were 30 s).For channel activation, shorter red and far-red light irradiations(10 s) had to be used to obtain an escape time of 20 s. Thedifference in the escape times suggests that there is relativelyrapid divergence in the transduction pathways leading from phytochromeactivation (only one molecular species of phytochrome is foundin Mougeotia) to each of the two responses in the same cellularsystem. Because channel activation occurs 2–4 min afterirradiation while the escape time is 20 s, it is unlikely thatphytochrome acts directly on the channel. (Received September 26, 1995; Accepted December 28, 1995)     

Effect of Purine and Pyrimidine Analogues on Growth and RNA Metabolism in the Soybean Hypocotyl-the Selective Action of 5-Fluorouracil

The effects of several base analogues and cycloheximide on RNA synthesis, protein synthesis, and cell elongation were studied in excised soybean hypocotyl. None of the pyrimidine analogues tested affected growth or protein synthesis; only 5-fluorouracil appreciably inhibited RNA synthesis. 8-Azaguanine and 6-methylpurine markedly inhibited RNA and protein synthesis and cell elongation. Cycloheximide effectively inhibited both cell elongation and protein synthesis.The results show that 5-fluorouracil selectively inhibited ribosomal and soluble RNA synthesis without affecting the synthesis of D-RNA. These results indicate that the requirement for RNA synthesis to support continued protein synthesis and cell elongation is restricted to the synthesis of D-RNA.5-Fluorouracil was incorporated into all classes of RNA in a form believed to be 5-fluorouridylic acid.Cycloheximide markedly inhibited the accumulation of ribosomal RNA, but the results indicate that CH did not inhibit, per se, the synthesis of ribosomal RNA. The accumulation of newly synthesized D-RNA was only slightly affected by cycloheximide. These results show that the inhibition of cell elongation by cycloheximide correlates with the inhibition of protein synthesis, but not with the effect on RNA metabolism.     

Phytochrome control mechanisms in leaf expansion of Phaseolus vulgaris cv. Limburg.

Abstract. The effectiveness of a red-light pulse acting through phytochrome in inducing primary leaf expansion in 9-d-old etiolated bean ( Phaseolus vulgaris L. ev. Limburg) seedlings is strongly increased by a continuous far-red light (CFR) pretreatment. This increase in effectiveness of a red pulse is positively correlated with the time and the fluence rate of the CFR pretreatment. Escape from photoreversibility of this red pulse after the CFR pretreatment is extremely slow (more than 3 d). When a dark period is interposed between the end of the CFR pretreatment and the inductive red pulse the photoreversible part of the response to this pulse is highly dependent upon the photostationary state of phytochrome at the onset of the dark period.
The results give strong evidence for the synergistic activity of two components of phytochrome action during leaf growth induction, one of them acting via a very stable Pfr fraction.