Partial characterization of the interaction between phytochrome and a particulate fraction of maize coleoptiles

Extraction of red light-irradiated maize coleoptiles with Mg⁺⁺-containingbuffers enhances the pelletability of phytochrome. The enhancedphytochrome pelletability is taken to represent in vivo interactionof phytochrome with its binding site. The bonds involved inthe interaction appear to be ionic. This is shown by the requirementof Mg⁺⁺ for the enhanced pelletability and for the maintenanceof phytochrome repelletability during subsequent fractionation.Also, the phytochrome-binding site complex is responsive tothe disruptive effect of high ionic strength buffers, but itisrelatively insensitive to pH changes. Due to the ionic natureof the interaction, the complex can withstand membrane dissolutionby the non-ionic detergent Triton X 100. Though the molecularbasis for the persistent re-pelletability of phytochrome afterdetergent treatment remains to be determined, data obtainedindicate that the phenomenon is not due to denaturation of thephytochrome molecule per se. (Received May 25, 1976; )     

In vivo phototransformation of phytochrome in relation to its binding to a particulate fraction of maize coleoptiles

When the phytochrome molecule of maize coleoptiles absorbs sufficientenergy it binds to its putative binding site in a particulatefraction irrespective of whether or not it is in the P_fr form.The extent of binding depends on the light dosage. Red lightis more efficient than far red light but both are effectivein causing phytochrome to bind. Using phytochrome binding tosubcellular particles as the prototype of a primary physiologicalresponse it is concluded that P_fr may not necessarily be theonly physiologically active form of phytochrome. (Received May 31, 1976; )     

Phytochrome is required for the occurrence of time-dependent phototropism in maize coleoptiles

Time-dependent phototropism (TDP), sometimes called second positive curvature, occurs when the duration of phototropic stimulation with blue light (B) exceeds a few minutes. TDP was characterized in maize (Zea mays L.) coleoptiles raised under continuous red light (R). Subsequently, coleoptiles adapted to darkness were used to investigate the effect of R on TDP. It was found that TDP, which is induced in R-grown coleoptiles, does not occur in dark-adapted coleoptiles and that dark-adapted coleoptiles begin to show TDP after treatment with R. The TDP responsiveness became maximal 1-2 h after treatment with a R pulse and decreased during the next few hours. At least 10 min was required after a short pulse of R before the coleoptile began to respond to B for the induction of TDP. The effect of R in establishing the TDP responsiveness was totally suppressed by a pulse of far-red light given immediately after an inductive pulse of R. It is concluded that the mechanism of TDP requires for its establishment a R signal perceived by phytochrome. The TDP of R-grown and R-pretreated coleoptiles showed relationships to stimulation times and fluence rates that are similar to those reported for oat coleoptiles, except that TDP of maize showed a sharp increase in its magnitude within a narrow range of stimulation times as short as 5-10 min.     

Establishment of far‐red high irradiance responses in wheat through transgenic expression of an oat phytochrome A gene

A transgenic wheat line over‐expressing an oat phytochrome A gene under the control of the constitutive maize ubiquitin promoter was generated using a biolistic particle delivery system from immature wheat embryos. The resulting line showed increased levels of total phytochrome A protein in both dark‐grown and light‐grown plants. When grown under continuous far‐red light, seedlings of this line showed additional inhibition of the coleoptile extension in comparison with wild‐type seedlings. Unlike the response of wild‐type seedlings to continuous far‐red, this additional inhibition was dependent on fluence rate and was not observed under half‐hourly pulses of far‐red delivering the same total fluence as the continuous irradiation treatment. These observations suggest that increase in phytochrome A levels in wheat leads to the establishment of a far‐red high irradiation reaction in this monocotyledonous plant. Exposure to continuous red light caused a similar inhibition of coleoptile extension in both the wild types and the transgenic seedlings. When wild‐type seedlings were grown under continuous far‐red, their coleoptiles remained completely colourless and first leaves remained tightly rolled. In contrast, transgenic seedlings grown in the same conditions produced significant levels of anthocyanins in their coleoptiles and their first leaves became unrolled. Taken together, our data suggest that the increased levels of phytochrome A in wheat can change the type of response of some developmental processes to light signals, leading to the generation of a high irradiance reaction which is otherwise absent in the wild types under the conditions used.     

The influence of de-etiolation on the sensitivity of Avena coleoptiles to the far-red absorbing form of phytochrome

In photoresponses regulated by phytochrome the effect of a red irradiation is not always reversed by far-red. This applies for instance to the influence of red light on the geotropic reactions of Avena coleoptiles. We could induce red/far-red reversibility by a short de-etiolating exposure to red light about 20 h prior to the experimental irradiations. This, was due to a decrease of the sensitivity to the low level of the far-red absorbing form of phytochrome that is established by far-red. Since etiolated plants react also to a wavelength of 520 nm (green light), it is advisable to expose the coleoptiles to a de-etiolating irradiation prior to manipulations in green safelight in order to prevent the plants from reacting to the green light.     

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     

Immunogold electron microscopy of phytochrome in Avena: identification of intracellular sites responsible for phytochrome sequestering and enhanced pelletability

Using monoclonal antibodies to the plant photoreceptor, phytochrome, we have investigated by immunogold electron microscopy the rapid, red light-induced, intracellular redistribution (termed "sequestering") of phytochrome in dark-grown Avena coleoptiles. Pre-embedding immunolabeling of 5-micron-thick cryosections reveals that sequestered phytochrome is associated with numerous, discrete structures of similar morphology. Specific labeling of these structures was also achieved by post-embedding ("on-grid") immunostaining of LR-White-embedded tissue, regardless of whether the tissue had been fixed chemically or by freeze substitution. The phytochrome-associated structures are globular to oval in shape, 200-400 nm in size, and are composed of amorphous, granular material. No morphologically identifiable membranes are present either surrounding or within these structures, which are often present as apparent aggregates that approach several micrometers in size. An immunogold labeling procedure has also been developed to identify the particulate, subcellular component with which phytochrome is associated in vitro as a consequence of irradiation of Avena coleoptiles before their homogenization. Structures with appearance similar to those identified in situ are the only components of the pelletable material that are specifically labeled with gold. We conclude that the association of phytochrome with these structures in Avena represents the underlying molecular event that ultimately is expressed both as red light-induced sequestering in vivo and enhanced pelletability of phytochrome detected in vitro.     

The Phototropic Responses of Avena Coleoptiles

Macleod, K., Firn, R. D. and Digby, J. 1986. The phototropicresponses of Avena coleoptiles.—J. exp. Bot. 37: 542–548. A number of studies of the elongation rate changes causing phototropismhave been made but the findings of different groups have notbeen entirely Consistent. Studies of oat coleoptile phototropismin response to first-positive and second-positive doses indicatethat no single pattern of elongation rate changes causes phototropismeven in a single species. The relative effect of phototropicstimulation on the elongation rate at the shaded or the illuminatedside of coleoptiles subject to unilateral illumination dependson physiological state of the cell-for instance its positionin the elongation zone or whether it has been given red lightrecently. Models of phototropism will have to account for sucha diversity of phototropic responses. The importance of makingfull elongation rate measurements has once again been demonstrated. Key words: Phototropism, first-positive, second-positive, phytochrome, coleoptile, elongation rate     

Phytochrome Responses to End-of-Day Irradiations in Light-grown Corn Grown in the Presence and Absence of Sandoz 9789

Corn seedlings were grown in white light in the absence and presence of the chlorosis-inducing herbicide San 9789. The resulting green and achlorophyllous seedlings were used to investigate phytochrome-mediated responses to end-of-day far red irradiation and reversal of these responses by subsequent red irradiation. Mesocotyl and coleoptile elongation increased in response to end-of-day far red irradiation, whereas the anthocyanin content of the coleoptiles was decreased. All three responses were reversible by red irradiation following the far red. Dose-response curves for far red induction and red reversal of these responses did not differ significantly for plants grown in the presence or absence of San 9789. Thus, San 9789 appears to affect neither phytochrome itself nor the response system involved. Chlorophyll screening likewise does not affect phytochrome relationships for these responses.     

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.     

Cross-linking Phytochrome to its Receptor in situ using Imidoesters

Phytochrome can be cross-linked to a particulate fraction usingimidoesters, namely dimethy adipimidate (DMA) and dimethyl suberimidate(DMS). DMS was more effective than DMA. Cross-linking of phytochrometo its in situ receptor effected by DMS occurred in red light-irradiatedcoleoptiles. If DMS cross-linking was carried out prior to redlight irradiation there was very little formation of particulatephytochrome. Phytochrome in the particulate fraction obtainedby in situ DMS cross-linking was totally resistant to the solubilizingeffect of washing with solutions of high salt concentrationand high pH and was indistinguishable spectro-scopically fromthe phytochrome in untreated coleoptiles. DMS cross-linkingof phytochrome to its assumed receptor in situ preferentiallyprotected it from destruction following red light irradiationand also prevented it from dissociating from its receptor followingR/FR¹ irradiation when incubated subsequently in the dark. Thesecharacteristics of phytochrome in DMS-treated coleoptiles matchedthose observed using glutaraldehyde as the cross-linking reagent.It is therefore concluded that earlier results obtained usingglutaraldehyde are not peculiar to that reagent and can be duplicatedreadily using more defined bifunctional cross-linkers.     

A red-far red reversible effect on uptake of exogenous indoleacetic Acid in etiolated rice coleoptiles

The uptake and accumulation of exogenous indoleacetic acid-¹⁴C by intact rice coleoptiles were examined. The absorption of exogenous indoleacetic acid was controlled by phytochrome, while the subsequent accumulation of this indoleacetic acid in various portions of the coleoptile was complex, and the effect of red light in this system was small compared to the alteration of the uptake of indoleacetic acid by red light. The absorption of indoleacetic acid exhibited two phases: the first occurring during the first 3-hour portion of the incubation was an inhibition, while the second was a promotive effect at about the 5th hour of incubation. Both of these effects were red, far redreversible, implicating phytochrome in this effect. Neither the destruction nor the immobilization of this exogenous indoleacetic acid apeared to be greatly affected by red light irradiation. The principal interaction between phytochrome and indoleacetic acid appears to occur during the absorption of exogenous indoleacetic acid. This effect may be related to the control by phytochrome of the amount of auxin which diffuses from coleoptile tips.     

In vivo phytochrome reversion in immature tissue of the alaska pea seedling

Reversion of far red-absorbing phytochrome to red-absorbing phytochrome without phytochrome destruction (that is, without loss of absorbancy and photoreversibility) occurs in the following tissues of etiolated Alaska pea seedlings (Pisum sativum L.): young radicles (24 hours after start of imbibition), young epicotyls (48 hours after start of imbibition), and the juvenile region of the epicotyl immediately subjacent to the plumule in older epicotyls. Reversion occurs rapidly in the dark during the first 30 minutes following initial phototransformation of red-absorbing phytochrome to far red-absorbing phytochrome. If these tissues are illuminated continuously with red light for 30 minutes, the total amount of phytochrome remains unchanged. Beyond 30 minutes after a single phototransformation or after the start of continuous red irradiation, phytochrome destruction commences. In young radicles, sodium azide inhibits this destruction, but does not affect reversion. In older tissues in which far red-absorbing phytochrome destruction begins immediately upon phototransformation, strong evidence for simultaneous far red-absorbing phytochrome reversion is obtained from comparison of far red-absorbing phytochrome loss in the dark following a single phototransformation with far red-absorbing phytochrome loss under continuous red light.     

Elongated mesocotyl1, a phytochrome-deficient mutant of maize

To begin the functional dissection of light signal transduction pathways of maize (Zea mays), we have identified and characterized the light-sensing mutant elm1 (elongated mesocotyl1). Seedlings homozygous for elm1 are pale green, show pronounced elongation of the mesocotyl, and fail to de-etiolate under red or far-red light. Etiolated elm1 mutants contain no spectrally active phytochrome and do not deplete levels of phytochrome A after red-light treatment. High-performance liquid chromatography analyses show that elm1 mutants are unable to convert biliverdin IX alpha to 3Z-phytochromobilin, preventing synthesis of the phytochrome chromophore. Despite the impairment of the phytochrome photoreceptors, elm1 mutants can be grown to maturity in the field. Mature plants retain aspects of the seedling phenotype and flower earlier than wild-type plants under long days. Thus, the elm1 mutant of maize provides the first direct evidence for phytochrome-mediated modulation of flowering time in this agronomically important species.     

Overexpression of rice phytochrome A partially complements phytochrome B deficiency in Arabidopsis

The red/far-red reversible phytochromes play a central role in regulating the development of plants in relation to their light environment. Studies on the roles of different members of the phytochrome family have mainly focused on light-labile, phytochrome A and light-stable, phytochrome B. Although these two phytochromes often regulate identical responses, they appear to have discrete photosensory functions. Thus, phytochrome A predominantly mediates responses to prolonged far-red light, as well as acting in a non-red/far-red-reversible manner in controlling responses to light pulses. In contrast, phytochrome B mediates responses to prolonged red light and acts photoreversibly under light-pulse conditions. However, it has been reported that rice (Oryza sativa L.) phytochrome A operates in a classical red/far-red reversible fashion following its expression in transgenic tobacco plants. Thus, it was of interest to determine whether transgenic rice phytochrome A could substitute for loss of phytochrome B in phyB mutants of Arabidopsis thaliana (L.) Heynh. We have observed that ectopic expression of rice phytochrome A can correct the reduced sensitivity of phyB hypocotyls to red light and restore their response to end-of-day far-red treatments. The latter is widely regarded as a hallmark of phytochrome B action. However, although transgenic rice phytochrome A can correct other aspects of elongation growth in the phyB mutant it does not restore other responses to end-of-day far-red treatments nor does it restore responses to low red:far-red ratio. Furthermore, transgenic rice phytochrome A does not correct the early-flowering phenotype of phyB seedlings. Received: 12 July 1998 / Accepted: 13 August 1998     

The physiological versus the spectrophotometric status of phytochrome in corn coleoptiles

The influence of red light in altering the phototropic sensitivity of corn coleoptiles (Zea mays L., cultivar Burpee Barbecue Hybrid) is compared with the spectrophotometric status of the phytochrome they contain. The distribution of measurable phytochrome corresponds roughly with the distribution of sensitivity to red light for physiological change. Both phytochrome concentration and red light sensitivity are maximal in the coleoptile tips. Red light pretreatments which reduce total phytochrome by about 50%, however, do not alter subsequent red light sensitivity of the phototropic system. Dosages of red light sufficient to saturate the physiological system are two orders of magnitude too small to induce measurable phytochrome transformation. The log-dosage-response curves for physiological change and for phytochrome transformation do not have the same slopes. The time course for appearance, mainconcentration of the far-red-absorbing form of phytochrome over a broad range of tenance, and decay of the physiological response is independent of the measurable concentrations. The following hypothesis is proposed: the phytochrome mediating the alteration in phototropic sensitivity is only a small proportion of the total present. This small active fraction is physically and kinetically independent of the bulk measurable, and is packaged in some manner which facilitates its transformation in both directions.     

Phytochrome Modification and Light-enhanced, In Vivo-induced Phytochrome Pelletability

Phytochrome that was induced by red irradiation in vivo to pellet with subcellular material and that was released from the pellet by removal of divalent cations exhibited altered characteristics. Compared to phytochrome extracted in a soluble red-absorbing form from etiolated tissue, pelleted and released phytochrome, which was also assayed in the red-absorbing form even though pelleted in the far-red-absorbing form, showed 50% greater micro complement fixation activity, eluted closer to the void volume of a Sephadex G-200 column, and electrophoresed more slowly on sodium dodecyl sulfate-polyacrylamide gels. Data presented here document that phytochrome pelleted in the far-red-absorbing form differs from soluble phytochrome extracted from nonirradiated tissue. These data, however, do not permit the conclusion that there is a causal relationship between pelletability and phytochrome modification.     

Pr-specific phytochrome phosphorylation in vitro by a protein kinase present in anti-phytochrome maize immunoprecipitates

Protein kinase activity has repeatedly been found to co-purify with the plant photoreceptor phytochrome, suggesting that light signals received by phytochrome may be transduced or modulated through protein phosphorylation. In this study immunoprecipitation techniques were used to characterize protein kinase activity associated with phytochrome from maize (Zea mays L.). A protein kinase that specifically phosphorylated phytochrome was present in washed anti-phytochrome immunoprecipitates of etiolated coleoptile proteins. No other substrate tested was phosphorylated by this kinase. Adding salts or detergents to disrupt low-affinity protein interactions reduced background phosphorylation in immunoprecipitates without affecting phytochrome phosphorylation, indicating that the protein kinase catalytic activity is either intrinsic to the phytochrome molecule or associated with it by high-affinity interactions. Red irradiation (of coleoptiles or extracts) sufficient to approach photoconversion saturation reduced phosphorylation of immunoprecipitated phytochrome. Subsequent far-red irradiation reversed the red-light effect. Phytochrome phosphorylation was stimulated about 10-fold by a co-immunoprecipitated factor. The stimulatory factor was highest in immunoprecipitates when Mg2+ was present in immunoprecipitation reactions but remained in the supernatant in the absence of Mg2+. These observations provide strong support for the hypothesis that phytochrome-associated protein kinase modulates light responses in vivo. Since only phytochrome was found to be phosphorylated, the co-immunoprecipitated protein kinase may function to regulate receptor activity.     

Phytochrome: A Re-examination of the Quaternary Structure

Highly purified phytochrome samples from rye (Secale Cereale cv. Cougar) were fractionated by ultracentrifugation in isokinetic sucrose density gradients. Three protein species were separated with estimated sedimentation coefficients of 6.5S, 8.0S, and 11.5S. The 6.5S and 8.0S forms contained photoreversible phytochrome and produced a single subunit of 120,000 molecular weight upon reduction and electrophoresis in the presence of sodium dodecyl sulfate. The 11.5S species contained no detectable phytochrome. Reduction and electrophoresis of the 11.5S species in the presence of sodium dodecyl sulfate produced a major polypeptide of 32,000 molecular weight and a minor polypeptide of 48,000 molecular weight. The square tetrameric structures, observed by electron microscopy and previously thought to be phytochrome molecules, were found to be due to the presence of this 11.5S species in phytochrome preparations.