Genetic Regulation of Development in Sorghum bicolor: VI. The ma(3) Allele Results in Abnormal Phytochrome Physiology

Physiological processes controlled by phytochrome were examined in three near-isogenic genotypes of Sorghum bicolor, differing at the allele of the third maturity gene locus. Seedlings of 58M (ma₃^R ma₃^R) did not show phytochrome control of anthocyanin synthesis. In contrast, seedlings of 90M (ma₃ma₃) and 100M (Ma₃Ma₃) demonstrated reduced anthocyanin synthesis after treatment with far red and reversal of the far red effect by red. De-etiolation of 48-hour-old 90M and 100M dark-grown seedlings occurred with 48 hours of continuous red. Dark-grown 58M seedlings did not de-etiolate with continuous red treatment. Treatment of seedlings with gibberellic acid or tetcyclacis, a gibberellin synthesis inhibitor, did not alter anthocyanin synthesis. Levels of chlorophyll and anthocyanin were lower in light-grown 58M seedlings than in 90M and 100M. Etiolated seedlings of all three genotypes have similar amounts of photoreversible phytochrome. Crude protein extracts from etiolated seedlings were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transferred to nitrocellulose. Phytochrome was visualized with Pea-25, a monoclonal antibody directed to phytochrome from etiolated peas. The samples from all three genotypes contained approximately equivalent amounts of a prominent, immunostaining band at 126 kD. However, the sample from 58M did not show a fainter, secondary band at 123 kD that was present in 90M and 100M. The identity and importance of this secondary band at 123 kD is unknown. We propose that 58M is a phytochrome-related mutant that contains normal amounts of photoreversible phytochrome and normal phytochrome protein when grown in the dark.     

Identification of a highly conserved domain on phytochrome from angiosperms to algae

A monoclonal antibody (Pea-25) directed to phytochrome from etiolated peas (Pisum sativum L., cv Alaska) binds to an antigenic domain that has been highly conserved throughout evolution. Antigenic cross-reactivity was evaluated by immunoblotting sodium dodecyl sulfate sample buffer extracts prepared from lyophilized tissue samples or freshly harvested algae. Pea-25 immunostained an approximately 120-kilodalton polypeptide from a variety of etiolated and green plant tissues, including both monocotyledons and dicotyledons. Moreover, Pea-25 immunostained a similarly sized polypeptide from the moss Physcomitrella, and from the algae Mougeotia, Mesotaenium, and Chlamydomonas. Because Pea-25 is directed to phytochrome, and because it stains a polypeptide about the size of oat phytochrome, it is likely that Pea-25 is detecting phytochrome in each case. The conserved domain that is recognized by Pea-25 is on the nonchromophore bearing, carboxyl half of phytochrome from etiolated oats. Identification of this highly conserved antigenic domain creates the potential to expand investigations of phytochrome at a cellular and molecular level to organisms, such as Chlamydomonas, that offer unique experimental advantages.     

Genetic Regulation of Development in Sorghum bicolor: II. Effect of the ma(3) Allele Mimicked by GA(3)

The photoperiodic behavior and other developmental and morphological differences of 11 maturity genotypes (as identified by JR Quinby 1967, Adv Agron 19: 267-305) of the milo group of Sorghum bicolor (L.) Moench were studied under 8, 10, 12, and 14 hour photoperiods. Sorghum is a quantitative short day plant. The genotypes studied differ in genes which modify photoperiodic behavior and thus maturity; the alleles are designated as Ma₁, ma₁, Ma₂, ma₂, Ma₃, ma₃, and ma₃^R (single symbols indicate homozygosity at the indicated gene loci). Based on floral initiation (differentiation) under 10, 12, and 14 hour photoperiods the 11 genotypes were assigned to three clases: (I) flower initiation delayed by 12 hour photoperiods (all genotypes with Ma₁Ma₂ but not ma₃^R), (II) flower initiation delayed by 14 hour photoperiods (all genotypes with Ma₁ma₂, ma₁Ma₂, or ma₁ma₂ but not ma₃^R), (III) flower initiation not drastically delayed by 14 hour photoperiods (all genotypes with ma₃^R). All of the class III genotypes were taller, had longer leaf sheaths, narrower and longer leaf blades, and less leaf area, than the other genotypes. In addition, the class III genotypes initiated rapid culm and thus internode elongation sooner after floral initiation than any of the class I or II genotypes. Dry weight did not differ between the class III genotypes and the others. The rate of leaf emergence in the class III genotypes and all others was indistinguishable until after floral initiation in the former. The allelic combination unique to class I, Ma₁Ma₂, makes plants very photoperiod sensitive without causing observable changes in morphology or other development events. The allelic combination unique to class III, ma₃^R, makes plants relatively photoperiod insensitive and results in several differences in morphology and development.     

Phytochrome Levels in Light-Grown Avena Change in Response to End-of-Day Irradiations

The effect of 15-minute end-of-day irradiations on photoreversible phytochrome levels in light-grown oat (Avena sativa L., cv Garry) seedlings was investigated. Oat seedlings were grown in a cycle of 8 hours of natural daylight and 16 hours of complete darkness, from sowing until harvest at day 10. The level of extractable, photoreversible phytochrome per unit fresh weight was 60% higher after end-of-day far-red irradiation than after either end-of-day red irradiation or end-of-day far-red followed by end-of-day red. Seedlings irradiated with end-of-day far-red also exhibited a small but significant increase in shoot height and fresh weight per seedling. Extracts of seedlings given each of these end-of-day treatments were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, electroblotted, and immunostained with monoclonal antibodies specific to different phytochromes. Regardless of end-of-day light treatment, phytochrome that is abundant in etiolated tissue was below the limit of detection, indicating that one or more of the phytochromes predominating in green tissue changes in abundance.     

Avena sativa L. contains three phytochromes,only one of which is abundant in etiolated tissue

Phytochrome from leaves of light-grown oat (Avena sativa L. cv. Garry) plants is characterized with newly generated monoclonal antibodies (MAbs) directed to it. The results indicate that there are at least two phytochromes in green oat leaves, each of which differs from the phytochrome that is most abundant in etiolated oat tissue. When analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) with reference to 124-kilodalton (kDa) phytochrome from etiolated oats, the two phytochromes from green oats have monomer sizes of 123 of 125 kDa. Immunoblot analysis of SDS, sample buffer extracts of lyophilized, green oat leaves indicates that neither the 125-kDa nor the 123-kDa polypeptide is a degradation product arising after tissue homogenization. Of the two, the 123-kDa phytochrome appears to be the predominant species in light-grown oat leaves. During SDS-PAGE in the presence of 1 mM Zn²⁺, 123-kDa phytochrome undergoes a mobility shift corresponding to an apparent mass increase of 2 kDa. In contrast, the electrophoretic mobility of 125-kDa phytochrome is unaffected by added Zn²⁺. Some MAbs that recognize 123-kDa phytochrome fail to recognize 125-kDa phytochrome and vice versa, indicating that these two phytochromes are not only immunochemically distinct from 124-kDa phytochrome, but also from each other. It is evident, therefore, that there are at least three phytochromes in an oat plant: 124-kDa phytochrome, which is most abundant in etiolated tissue, plus 123-and 125-kDa phytochromes, which predominate in light-grown tissue.Abbreviations Da Dalton - HA hydroxyapatite - MAb monoclonal antibody - PAb polyclonal antibody preparation - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulfate This research was supported by the U.S. Department of Energy (contract DE-AC-09-81SR10925 to L.H.P.). We thank Dr. Alan Jones, Department of Biology, University of North Carolina, Chapel Hill, USA, for kindly providing rabbit antiserum 4032, and Mrs. Donna Tucker and Mrs. Danielle Neal for their technical assistance.     

Genetic Regulation of Development in Sorghum bicolor: V. The ma(3) Allele Results in Gibberellin Enrichment

Sorghum bicolor genotypes, near isogenic with different alleles at the third maturity locus, were compared for development, for responsiveness to GA₃ and a GA synthesis inhibitor, and occurrence and concentrations of endogenous GAs, IAA, and ABA. At 14 days the genotype 58M (ma₃^Rma₃^R) exhibited 2.5-fold greater culm height, 1.75-fold greater total height, and 1.38-fold greater dry weight than 90M (ma₃ma₃) or 100M (Ma₃Ma₃). All three genotypes exhibited similar shoot elongation in response to GA₃, and 58M showed GA₃-mediated hastening of floral initiation when harvested at day 18 or 21. Both 90M and 100M had exhibited hastening of floral initiation by GA₃ previously, at later application dates. Tetcyclacis reduced height, promoted tillering, and delayed flowering of 58M resulting in plants which were near phenocopies of 90M and 100M. Based on bioassay activity, HPLC retention times, cochromatography with ²H₂-labeled standards on capillary column GC and matching mass spectrometer fragmentation patterns (ions [m/z] and relative abundances), GA₁, GA₁₉, GA₂₀, GA₅₃, and GA₃ were identified in extracts of all three genotypes. In addition, based on published Kovats retention index values and correspondence in ion masses and relative abundances, GA₄₄ and GA₁₇ were detected. Quantitation was based on recovery of coinjected, ²H₂-labeled standards. In 14 day-old-plants, total GA-like bioactivity and GA₁ concentrations (nanograms GA/gram dry weight) were two- to six-fold higher in 58M than 90M and 100M in leaf blades, apex samples, and whole plants while concentrations in culms were similar. Similar trends occurred if data were expressed on a per plant basis. GA₁ concentrations for whole plants were about two-fold higher in 58M than 90M and 100M from day 7 to day 14. Concentrations of ABA and IAA did not vary between the genotypes. The results indicate the mutant allele ma₃^R causes a two- to six-fold increase in GA₁ concentrations, does not result in a GA-receptor or transduction mutation and is associated with phenotypic characteristics that can be enhanced by GA₃ and reduced by GA synthesis inhibitor. These observations support the hypothesis that the allele ma₃^R causes an overproduction of GAs which results in altered leaf morphology, reduced tillering, earlier flowering, and other phenotypic differences between 58M and 90M or 100M.     

Photoperiod Control of Gibberellin Levels and Flowering in Sorghum

Regulation of rhythmic peaks in levels of endogenous gibberellins (GAs) by photoperiod was studied in the short-day monocot sorghum (Sorghum bicolor [L.] Moench). Comparisons were made between three maturity (Ma) genotypes: 58M (Ma₁Ma₁, Ma₂Ma₂, phyB-1phyB-1, and Ma₄Ma₄ [a phytochrome B null mutant]); 90M (Ma₁Ma₁, Ma₂Ma₂, phyB-2phyB-2, and Ma₄Ma₄); and 100M (Ma₁Ma₁, Ma₂Ma₂, PHYBPHYB, and Ma₄Ma₄). Plants were grown for 14 d under 10-, 14-, 16-, 18-, and 20-h photoperiods, and GA levels were assayed by gas chromatography-mass spectrometry every 3 h for 24 h. Under inductive 10-h photoperiods, the peak of GA₂₀ and GA₁ levels in 90M and 100M was shifted from midday, observed earlier with 12-h photoperiods, to an early morning peak, and flowering was hastened. In addition, the early morning peaks in levels of GA₂₀ and GA₁ in 58M under conditions allowing early flowering (10-, 12-, and 14-h photoperiods) were shifted to midday by noninductive (18- and 20-h) photoperiods, and flowering was delayed. These results are consistent with the possibility that the diurnal rhythm of GA levels plays a role in floral initiation and may be one way by which the absence of phytochrome B causes early flowering in 58M under most photoperiods.     

Temporal and light regulation of the expression of three phytochromes in germinating seeds and young seedlings of Avena sativa L.

An oat (Avena sativa L.) plant contains at least three phytochromes, which have monomeric masses of 125, 124, and 123 kilodaltons (kDa) (Wang et al., 1991, Planta 184, 96–104). The 124-kDa phytochrome is most abundant in dark-grown seedlings, while the other two phytochromes predominate in light-grown seedlings. Using three monoclonal antibodies, each specific to one of the three phytochromes, we have monitored by immunoblot assay the expression of these three phytochromes in the 5 d following onset of imbibition of seeds. On a per-organism basis, each of these three phytochromes increased in abundance for the first 3 d in the light, or for the first 4 d in darkness, after which they each began to decrease in quantity. When 3-d-old dark-grown seedlings were transferred to the light, the abundance of each of these three phytochromes decreased both in absolute amount and relative to the phytochrome levels in control seedlings kept in darkness. In contrast, when 3-d-old light-grown seedlings were transferred to darkness, the abundance of the 124-kDa and 125-kDa phytochromes increased while that of 123-kDa phytochrome remained unchanged. In each case, the level of phytochrome was greater than that of control seedlings maintained in the light. Thus, in addition to temporal regulation, all three phytochromes exhibit photoregulated expression at the protein level, although the magnitude of this photoregulation varies substantially. We thank Drs. Elizabeth Williams and Tammy Sage (Botany Department, University of Georgia, USA) for generously permitting us to use their image-analysis system. This research was supported by USDA NRICGP grant 91-37100-6490.     

Characterization of Green Tissue-Specific Phytochrome Isolated Immunochemically from Pea Seedlings

Phytochrome was isolated and purified from light-grown pea (Pisumsativum) seedlings and compared with that from dark-grown seedlingsin terms of spectral and immunochemical properties. Approximately40% of phytochrome in the brushite eluate prepared from light-grownpea tissue bound with a monoclonal anti-pea phytochrome antibody(mAP3), but the remaining 60% did not. Both phytochrome fractionsshowed a typical photoreversible absorbance change after alternatered and far-red actinic irradiations, which was similar to thatof phytochrome from etiolated pea tissue. The peptide mappingof the mAP3-bound phytochrome from light-grown tissue was essentiallythe same as that of the mAP3-bound phytochrome from etiolatedtissue. However, the digestion pattern of the phytochrome thatwas prepared from light-grown tissue but which did not bindto mAP3 was obviously different from that of mAP3-bound phytochrome.Polyclonal anti-pea phytochrome antibodies and mAP5 and 10,however, bound to both the phytochromes. These results suggestthat light-grown tissue contains two phytochrome pools whichare distinct from each other with respect to the primary structureof the phytochrome polypeptide but which share a few commondeterminant sites. ¹ Permanent address: Department of Biology, Faculty of Science,Tokyo Metropolitan University, Fukazawa, Tokyo 158, Japan (H.A.), and Department of Botany, Faculty of Science, Universityof Tokyo, Hongo, Tokyo 113, Japan (M. F.).     

Expression of functional oat phytochrome A in transgenic rice.

To investigate the biological functions of phytochromes in monocots, we generated, by electric discharge particle bombardment, transgenic rice (Oryza sativa cv Gulfmont) that constitutively expresses the oat phytochrome A apoprotein. The introduced 124-kD polypeptide bound chromophore and assembled into a red- and far-red-light-photoreversible chromoprotein with absorbance spectra indistinguishable from those of phytochrome purified from etiolated oats. Transgenic lines expressed up to 3 and 4 times more spectrophotometrically detectable phytochrome than wild-type plants in etiolated and green seedlings, respectively. Upon photo-conversion to the far-red-absorbing form of phytochrome, oat phytochrome A was degraded in etiolated seedlings with kinetics similar to those of endogenous rice phytochromes (half-life approximately 20 min). Although plants overexpressing phytochrome A were phenotypically indistinguishable from wild-type plants when grown under high-fluence white light, they were more sensitive as etiolated seedlings to light pulses that established very low phytochrome equilibria. This indicates that the introduced oat phytochrome A was biologically active. Thus, rice ectopically expressing PHY genes may offer a useful model to help understand the physiological functions of the various phytochrome isoforms in monocotyledonous plants.     

Protein Differences between Two Isogenic Cultivars of Barley (Hordeum vulgare L.) that Differ in Sensitivity to Photoperiod and Far-Red Light

A photoperiodically sensitive cultivar of barley (Hordeum vulgare L. Shabet) (BMDR-8) and an isogenic, single-gene recessive mutant of this genotype that is insensitive to photoperiod (BMDR-1) were grown under continuous cool white light with or without supplemental far-red fluorescent light. BMDR-1 initiates flowers 6 days after germination, irrespective of light treatment, whereas BMDR-8 remains vegetative for at least a week longer, even in continuous light. When far-red light is added, the delay of flowering in BMDR-8 is overcome and both genotypes initiate floral primordia at the same time. Total phenol extracted proteins of seedlings of both genotypes were resolved by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. No protein differences were found between the genotypes when isoelectric focusing gels were run in the first dimension. Two qualitative genotypic differences were found when nonequilibrium pH gradient gel electrophoresis was run in the first dimension. An 85-kilodalton polypeptide (A) and a 26-kilodalton polypeptide (B) were always present in BMDR-8 but never found in BMDR-1. The levels of A appeared to decrease from the BMDR-8 during the first 3 days of far-red treatment but did not disappear completely even after 6 days of growth in the presence of farred. Polypeptide B decreases rapidly in continuous cool white light but is stabilized by far-red. The phytochrome content of BMDR-1 was found to be greater than that for BMDR-8. This increase appears to be caused by the type I (etiolated-tissue abundant) phytochrome pool, even in plants grown in continuous light.     

A single red-light pulse leads to a block of greening in the high-pigment-1 mutant of tomato

A single pulse of red light (R) given to 4-d-old etiolated high-pigment-1 (hp-1) mutant tomato (Solanum lycopersicum L.) seedlings followed by a 3-d dark period is demonstrated to result in a block of greening in subsequent white light. Wild-type seedlings green normally under this regime. The block of greening in the hp-1 mutant depends on the length of the dark period before and after the R pulse and operates via the low-fluence-response mode of phytochrome action. This block of greening takes place in hp-1 double mutants lacking either phytochrome A or phytochrome B1, but is absent in the hp-1 triple mutant lacking both phytochromes A and B1. These observations enable a screen to be devised for new phytochrome B1 mutants either within the photoreceptor or mutants defective in phytochrome B1-signalling steps which result in loss of capacity to green, by mutagenising the phytochrome A-deficient hp-1, fri double mutant. Received: 20 February 1998 / Accepted: 18 June 1998     

Identification of two loci involved in phytochrome expression in Nicotiana plumbaginifolia and lethality of the corresponding double mutant

Four Nicotiana plumbaginifolia mutants exhibiting long hypocotyls and chlorotic cotyledons under white light, have been isolated from M2 seeds following mutagenesis with ethyl methane sulphonate. In each of these mutants, this partly etiolated in white light (pew) phenotype is due to a recessive nuclear mutation at a single locus. Complementation analysis indicates that three mutants, dap5, ems28 and ems3-6-34, belong to a single complementation group called pew1, while dap1 defines the pew2 locus. The mutants at pew1 contain normal levels of immunochemically detectable apoprotein of the phytochrome that is relatively abundant in etiolated seedlings, but are deficient in spectrophotometrically detectable phytochrome, whether seedlings are grown in darkness or light. Moreover, biliverdin, a precursor of the phytochrome chromophore, restores light-regulated responses in pew1 mutants and increases their level of photoreversible phytochrome when grown in darkness. These results indicate that the pew1 locus may be involved in chromophore biosynthesis. The mutant at the pew2 locus displays no photoreversible phytochrome in etiolated seedlings, but does contain normal levels of photoreversible phytochrome when grown in the light. Biliverdin had little effect on light-regulated responses in this mutant. In addition, biliverdin did not alter the level of phytochrome in etiolated seedlings. These observations lead us to propose that this mutant could be affected in the phyA gene itself. We have also obtained the homozygous double mutant at the pew1 and pew2 loci. This double mutant is lethal at an early stage of development, consistent with a critical role for phytochrome in early development of higher plants.     

Patterns of expression and normalized levels of the five Arabidopsis phytochromes

Using monoclonal antibodies specific for each apoprotein and full-length purified apoprotein standards, the levels of the five Arabidopsis phytochromes and their patterns of expression in seedlings and mature plants and under different light conditions have been characterized. Phytochrome levels are normalized to the DNA content of the various tissue extracts to approximate normalization to the number of cells in the tissue. One phytochrome, phytochrome A, is highly light labile. The other four phytochromes are much more light stable, although among these, phytochromes B and C are reduced 4- to 5-fold in red- or white-light-grown seedlings compared with dark-grown seedlings. The total amount of extractable phytochrome is 23-fold lower in light-grown than dark-grown tissues, and the percent ratios of the five phytochromes, A:B:C:D:E, are measured as 85:10:2:1.5:1.5 in etiolated seedlings and 5:40:15:15:25 in seedlings grown in continuous white light. The four light-stable phytochromes are present at nearly unchanging levels throughout the course of development of mature rosette and reproductive-stage plants and are present in leaves, stems, roots, and flowers. Phytochrome protein expression patterns over the course of seed germination and under diurnal and circadian light cycles are also characterized. Little cycling in response to photoperiod is observed, and this very low amplitude cycling of some phytochrome proteins is out of phase with previously reported cycling of PHY mRNA levels. These studies indicate that, with the exception of phytochrome A, the family of phytochrome photoreceptors in Arabidopsis constitutes a quite stable and very broadly distributed array of sensory molecules.     

De novo synthesis of phytochrome in pumpkin hooks

Phytochrome becomes density labeled in the hook of pumpkin (Cucurbita pepo L.) seedlings grown in the dark on D₂O, indicating that the protein moiety of the pigment is synthesized de novo during development. Red light causes a rapid decline of the total phytochrome level in the hook of etiolated seedlings but upon return to the dark, phytochrome again accumulates. These newly appearing molecules are also synthesized de novo. Newly synthesized phytochrome in both dark-grown and red-irradiated seedlings is in the red-absorbing form. Turnover of the red-absorbing form is indicated by the density labeling of phytochrome during a period when the total phytochrome level in the hook of dark-grown seedlings remains constant. However, it was not possible to determine whether this results from intracellular turnover or turnover of the whole cell population during hook growth.     

The roles of phytochromes in elongation and gravitropism of roots

Gravitropic orientation and the elongation of etiolated hypocotyls are both regulated by red light through the phytochrome family of photoreceptors. The importance of phytochromes A and B (phyA and phyB) in these red light responses has been established through studies using phy mutants. To identify the roles that phytochromes play in gravitropism and elongation of roots, we studied the effects of red light on root elongation and then compared the gravitropic curvature from roots of phytochrome mutants of Arabidopsis (phyA, phyB, phyD and phyAB) with wild type. We found that red light inhibits root elongation approximately 35% in etiolated seedlings and that this response is controlled by phytochromes. Roots from dark- and light-grown double mutants (phyAB) and light-grown phyB seedlings have reduced elongation rates compared with wild type. In addition, roots from these seedlings (dark/light-grown phyAB and light-grown phyB) have reduced rates of gravitropic curvature compared with wild type. These results demonstrate roles for phytochromes in regulating both the elongation and gravitropic curvature of roots.     

Monoclonal antibodies directed to phytochrome from green leaves of Avena sativa L. cross-react weakly or not at all with the phytochrome that is most abundant in etiolated shoots of the same species

Seven monoclonal antibodies (MAbs) have been prepared to phytochrome from green oat (Avena sativa L. cv. Garry) leaves. One of these MAbs (GO-1) cross-reacts with apoprotein of the phytochrome that is most abundant in etiolated oat shoots as assessed by immunoblot assay of fusion proteins expressed in Escherichia coli. The epitope for this MAb is located between amino acids 618 and 686 in the primary sequence of type 3 phytochrome (Hershey et al. 1985, Nucleic Acids Res. 13, 8543–8559), which is one of the predominant phytochromes in etiolated oats. Three other MAbs (GO-4, GO-5, GO-6) immunoprecipitate phytochrome isolated from green oat leaves, as evaluated by photoreversibility assay. GO-1, GO-4, GO-5 and GO-6 are therefore directed to phytochrome. While evidence obtained with the other three MAbs (GO-2, GO-7, GO-8) strongly indicates that they are also directed to phytochrome, this evidence is not as rigorous. Recognition of antigen by any of these seven MAbs is not significantly reduced by periodate oxidation, indicating that their epitopes probably do not include carbohydrate. All but GO-1 bind either very poorly or not at all the phytochrome that is abundant in etiolated oat shoots. These data reinforce earlier observations made with antibodies directed to phytochrome from etiolated oats, indicating (1) that the phytochromes that predominate in etiolated and green oats differ immunochemically and (2) that phytochrome preparations from green oat leaves contain very little of the phytochrome that is abundant in etiolated shoots. An hypothesis that these two immunochemically distinct phytochromes form heterodimers in vitroAbbreviations Da Dalton - DEAE diethylaminoethyl - ELISA enzyme-linked immunosorbent assay - HA hydroxyapatite - Ig immunoglobulin - MAb monoclonal antibody - SDS sodium dodecyl sulfate is supported by comparison of immunoblot data obtained with conventionally purified phytochrome from etiolated oats to that expressed as fusion protein in E. coli. This research was supported by the U.S. Department of Energy (contract DE-AC-09-81SR10925 to L.H.P.). We thank Dr. Lyle Crossland and Ms. Sue Kadwell for their assistance in the construction of the cDNA clones, and Dr. Gyorgy Bisztray for providing us with clone pCBP3712. Dr. Phillip Evans and Dr. Russell Malmberg kindly provided MAbs 4F3, 6F12 and 8C10, as well as a corresponding antigen preparation. The excellent technical assistance of Mrs. Donna Tucker and Mrs. Danielle Neal is gratefully acknowledged.     

Boron-regulated hypocotyl elongation is affected in Arabidopsis mutants with defects in light signalling pathways

We studied the effect of elevated boron (B) concentrations on the growth and development of Arabidopsis thaliana in vitro with respect to different light conditions. Two basic responses were observed. At high concentrations (above 5 mM) a clear toxicity effect of B on plant growth was apparent. Seedlings were short, stunted and pale. However at concentrations between 1 and 3 mM H₃BO₃, hypocotyl elongation was stimulated in all Arabidopsis ecotypes tested relative to plants grown at 0.1 mM H₃BO₃. The stimulation of hypocotyl elongation by elevated B was proportionally greater with increasing irradiance. We also showed that blue light (BL) and red light (RL) did not alter the sensitivity of Arabidopsis hypocotyls to boron, but, dependent on genotype, BL and RL increased or reduced capacity of boron-induced hypocotyl elongation. Analysis of photomorphogenic mutants indicated the existence of an interaction between boron and light signalling pathways during plant growth and development. This interaction was supported by the observation that the expression of the BOR1 gene in Arabidopsis hypocotyls was stimulated by BL and RL. Our results suggest that in etiolated or light-grown seedlings the stimulation of hypocotyl growth by boron can be mediated by cryptochromes and phytochromes.     

Replacement of light by dibutyryl-CAMP and CAMP in betacyanin synthesis

The effect of adenosine 3′,5′-cyclic monophosphate and its N⁶,O^2′- dibutyryl derivative (Bu₂-CAMP) on betacyanin formation in etiolated Amaranthus paniculatus seedlings was investigated. Both substances can replace the action of light in the synthesis of these pigments, the formation of which is controlled by phytochrome. The specificity of this mimicry is underlined by the observations that sodium butyrate does not promote any betacyanin formation and that theophylline enhances the effect of Bu₂-AMP. Puromycin inhibits the induction of betacyanin synthesis by Bu₂-CAMP just as it does the light-induced pigment formation. These findings suggest that phytochrome exerts its controlling role in the synthesis of betacyanins through the agency of CAMP.