Affinity labeling of Avena phytochrome with ATP analogs

The presence of ATP-dependent, polycation-stimulated protein kinase activity in highly purified phytochrome preparations [Wong, Y.-S., Cheng, H.-C., Walsh, D. A. & Lagarias, J. C. (1986) J. Biol. Chem. 261, 12089-12097] has renewed the hypothesis that the phytochrome photoreceptor possesses enzymatic activity. A prerequisite for protein kinase function is the presence of an ATP binding site. Here we present evidence for a nucleoside triphosphate binding site(s) in the phytochrome molecule. Two ATP analogs, 5'-p-fluorosulfonylbenzoyladenosine and 8-azidoadenosine 5'-triphosphate, were used to affinity label purified Avena phytochrome. Labeling with both reagents is stimulated by the polycations poly(Lys(75),Ala(25)) and histone H1. Coincubation with ATP inhibits the polycation-stimulated labeling of phytochrome. In similar experiments GTP, CTP, UTP, ADP, and pyrophosphate, but not adenosine or AMP, also prevent photoaffinity labeling of phytochrome.

Self-assembly of synthetic phytochrome holoprotein in vitro

The phytochrome holoprotein of plants requires a covalently bound linear tetrapyrrole (bilin) prosthetic group for its photoreceptor function. Here we show that synthetic phytochrome apoprotein prepared by transcription and translation of an Avena phytochrome cDNA construct combines in vitro with phycocyanobilin, an analog of the natural chromophore, to produce a photoactive holoprotein. These results indicate that holoprotein assembly is an "autocatalytic" process.

Genetic engineering of phytochrome biosynthesis in bacteria

The bilin prosthetic groups of the phytochrome photoreceptors and the light-harvesting phycobiliprotein antennae arise from the oxygen-dependent ring opening of heme. Two ferredoxin-dependent enzymes contribute to this conversion: a heme oxygenase and a bilin reductase with discrete double-bond specificity. Using a dual plasmid system, one expressing a truncated cyanobacterial apophytochrome 1, Cph1(N514), and the other expressing a two-gene operon consisting of a heme oxygenase and a bilin reductase, these studies establish the feasibility of producing photoactive phytochromes in any heme-containing cell. Heterologous expression systems for phytochromes not only will facilitate genetic analysis of their assembly, spectrophotometric activity, and biological function, but also might afford the means to regulate gene expression by light in nonplant cells.

Purification and biochemical properties of phytochromobilin synthase from etiolated oat seedlings

Plant phytochromes are dependent on the covalent attachment of the linear tetrapyrrole chromophore phytochromobilin (P Phi B) for photoactivity. In planta, biliverdin IX alpha (BV) is reduced by the plastid-localized, ferredoxin (Fd)-dependent enzyme P Phi B synthase to yield 3Z-P Phi B. Here, we describe the >50,000-fold purification of P Phi B synthase from etioplasts from dark-grown oat (Avena sativa L. cv Garry) seedlings using traditional column chromatography and preparative electrophoresis. Thus, P Phi B synthase is a very low abundance enzyme with a robust turnover rate. We estimate the turnover rate to be >100 s(-1), which is similar to that of mammalian NAD(P)H-dependent BV reductase. Oat P Phi B synthase is a monomer with a subunit mass of 29 kD. However, two distinct charged forms of the enzymes were identified by native isoelectric focusing. The ability of P Phi B synthase to reduce BV is dependent on reduced 2Fe-2S Fds. A K(m) for spinach (Spinacea oleracea) Fd was determined to be 3 to 4 microM. P Phi B synthase has a high affinity for its bilin substrate, with a sub-micromolar K(m) for BV.

Functional genomic analysis of the HY2 family of ferredoxin-dependent bilin reductases from oxygenic photosynthetic organisms

Phytobilins are linear tetrapyrrole precursors of the light-harvesting prosthetic groups of the phytochrome photoreceptors of plants and the phycobiliprotein photosynthetic antennae of cyanobacteria, red algae, and cryptomonads. Previous biochemical studies have established that phytobilins are synthesized from heme via the intermediacy of biliverdin IX alpha (BV), which is reduced subsequently by ferredoxin-dependent bilin reductases with different double-bond specificities. By exploiting the sequence of phytochromobilin synthase (HY2) of Arabidopsis, an enzyme that catalyzes the ferredoxin-dependent conversion of BV to the phytochrome chromophore precursor phytochromobilin, genes encoding putative bilin reductases were identified in the genomes of various cyanobacteria, oxyphotobacteria, and plants. Phylogenetic analyses resolved four classes of HY2-related genes, one of which encodes red chlorophyll catabolite reductases, which are bilin reductases involved in chlorophyll catabolism in plants. To test the catalytic activities of these putative enzymes, representative HY2-related genes from each class were amplified by the polymerase chain reaction and expressed in Escherichia coli. Using a coupled apophytochrome assembly assay and HPLC analysis, we examined the ability of the recombinant proteins to catalyze the ferredoxin-dependent reduction of BV to phytobilins. These investigations defined three new classes of bilin reductases with distinct substrate/product specificities that are involved in the biosynthesis of the phycobiliprotein chromophore precursors phycoerythrobilin and phycocyanobilin. Implications of these results are discussed with regard to the pathways of phytobilin biosynthesis and their evolution.

The Arabidopsis HY2 gene encodes phytochromobilin synthase, a ferredoxin-dependent biliverdin reductase

Light perception by the plant photoreceptor phytochrome requires the tetrapyrrole chromophore phytochromobilin (P Phi B), which is covalently attached to a large apoprotein. Arabidopsis mutants hy1 and hy2, which are defective in P Phi B biosynthesis, display altered responses to light due to a deficiency in photoactive phytochrome. Here, we describe the isolation of the HY2 gene by map-based cloning. hy2 mutant alleles possess alterations within this locus, some of which affect the expression of the HY2 transcript. HY2 encodes a soluble protein precursor of 38 kD with a putative N-terminal plastid transit peptide. The HY2 transit peptide is sufficient to localize the reporter green fluorescent protein to plastids. Purified mature recombinant HY2 protein exhibits P Phi B synthase activity (i.e., ferredoxin-dependent reduction of biliverdin IX alpha to P Phi B), as confirmed by HPLC and by the ability of the bilin reaction products to combine with apophytochrome to yield photoactive holophytochrome. Database searches and hybridization studies suggest that HY2 is a unique gene in the Arabidopsis genome that is related to a family of proteins found in oxygenic photosynthetic bacteria.

The Arabidopsis HY2 gene encodes phytochromobilin synthase, a ferredoxin-dependent biliverdin reductase

Light perception by the plant photoreceptor phytochrome requires the tetrapyrrole chromophore phytochromobilin (P Phi B), which is covalently attached to a large apoprotein. Arabidopsis mutants hy1 and hy2, which are defective in P Phi B biosynthesis, display altered responses to light due to a deficiency in photoactive phytochrome. Here, we describe the isolation of the HY2 gene by map-based cloning. hy2 mutant alleles possess alterations within this locus, some of which affect the expression of the HY2 transcript. HY2 encodes a soluble protein precursor of 38 kD with a putative N-terminal plastid transit peptide. The HY2 transit peptide is sufficient to localize the reporter green fluorescent protein to plastids. Purified mature recombinant HY2 protein exhibits P Phi B synthase activity (i.e., ferredoxin-dependent reduction of biliverdin IX alpha to P Phi B), as confirmed by HPLC and by the ability of the bilin reaction products to combine with apophytochrome to yield photoactive holophytochrome. Database searches and hybridization studies suggest that HY2 is a unique gene in the Arabidopsis genome that is related to a family of proteins found in oxygenic photosynthetic bacteria.

Biliverdin reductase-induced phytochrome chromophore deficiency in transgenic tobacco

Targeted expression of mammalian biliverdin IXalpha reductase (BVR), an enzyme that metabolically inactivates linear tetrapyrrole precursors of the phytochrome chromophore, was used to examine the physiological functions of phytochromes in the qualitative short-day tobacco (Nicotiana tabacum cv Maryland Mammoth) plant. Comparative phenotypic and photobiological analyses of plastid- and cytosol-targeted BVR lines showed that multiple phytochrome-regulated processes, such as hypocotyl and internode elongation, anthocyanin synthesis, and photoperiodic regulation of flowering, were altered in all lines examined. The phytochrome-mediated processes of carotenoid and chlorophyll accumulation were strongly impaired in plastid-targeted lines, but were relatively unaffected in cytosol-targeted lines. Under certain growth conditions, plastid-targeted BVR expression was found to nearly abolish the qualitative inhibition of flowering by long-day photoperiods. The distinct phenotypes of the plastid-targeted BVR lines implicate a regulatory role for bilins in plastid development or, alternatively, reflect the consequence of altered tetrapyrrole metabolism in plastids due to bilin depletion.

Defining the bilin lyase domain: lessons from the extended phytochrome superfamily

Through pattern searches of genomic databases, new members of the growing family of phytochrome-related genes were identified and used to construct a 130-180 amino acid motif that delimits the bilin lyase domain, a subdomain of the extended phytochrome family that is sufficient for covalent attachment of linear tetrapyrroles (bilins). To test this hypothesis, portions of locus sll0821, a novel phytochrome-related gene from Synechocystis sp. PCC6803 that encodes a large protein with two potential bilin binding sites, were amplified, and the recombinant apoproteins were tested for bilin binding and phytochrome photoactivity. Our experiments indicated that both sites of this protein, termed Cph2 for cyanobacterial phytochrome 2, possessed bilin lyase activity, revealing two distinct classes of bilin lyase domains--those whose bilin adducts are red, far-red reversible and a second class whose bilin adducts are nonphotochromic. Spectroscopic analysis of photochromic phycocyanobilin and fluorescent phycoerythrobilin adducts of a 24-kDa fragment of Cph2 definitively established that the motif identified by pattern searches represents a bona fide bilin lyase domain. Site-directed mutagenesis of highly conserved charged residues within bilin lyase domains of nearly all members of the extended phytochrome superfamily has identified a glutamate residue critical for bilin binding.

Probing the photoreaction mechanism of phytochrome through analysis of resonance Raman vibrational spectra of recombinant analogues

Resonance Raman spectra of native and recombinant analogues of oat phytochrome have been obtained and analyzed in conjunction with normal mode calculations. On the basis of frequency shifts observed upon methine bridge deuteration and vinyl and C(15)-methine bridge saturation of the chromophore, intense Raman lines at 805 and 814 cm(-)(1) in P(r) and P(fr), respectively, are assigned as C(15)-hydrogen out-of-plane (HOOP) wags, lines at 665 cm(-)(1) in P(r) and at 672 and 654 cm(-)(1) in P(fr) are assigned as coupled C=C and C-C torsions and in-plane ring twisting modes, and modes at approximately 1300 cm(-)(1) in P(r) are coupled N-H and C-H rocking modes. The empirical assignments and normal mode calculations support proposals that the chromophore structures in P(r) and P(fr) are C(15)-Z,syn and C(15)-E,anti, respectively. The intensities of the C(15)-hydrogen out-of-plane, C=C and C-C torsional, and in-plane ring modes in both P(r) and P(fr) suggest that the initial photochemistry involves simultaneous bond rotations at the C(15)-methine bridge coupled to C(15)-H wagging and D-ring rotation. The strong nonbonded interactions of the C- and D-ring methyl groups in the C(15)-E,anti P(fr) chromophore structure indicated by the intense 814 cm(-1) C(15) HOOP mode suggest that the excited state of P(fr) and its photoproduct states are strongly coupled.

Modification of distinct aspects of photomorphogenesis via targeted expression of mammalian biliverdin reductase in transgenic Arabidopsis plants

The phenotypic consequences of targeted expression of mammalian biliverdin IXalpha reductase (BVR), an enzyme that metabolically inactivates the linear tetrapyrrole precursors of the phytochrome chromophore, are addressed in this investigation. Through comparative phenotypic analyses of multiple plastid-targeted and cytosolic BVR transgenic Arabidopsis plant lines, we show that the subcellular localization of BVR affects distinct subsets of light-mediated and light-independent processes in plant growth and development. Regardless of its cellular localization, BVR suppresses the phytochrome-modulated responses of hypocotyl growth inhibition, sucrose-stimulated anthocyanin accumulation, and inhibition of floral initiation. By contrast, reduced protochlorophyll levels in dark-grown seedlings and fluence-rate-dependent reduction of chlorophyll occur only in transgenic plants in which BVR is targeted to plastids. Together with companion analyses of the phytochrome chromophore-deficient hy1 mutant, our results suggest a regulatory role for linear tetrapyrroles within the plastid compartment distinct from their assembly with apophytochromes in the cytosol.

PKS1, a substrate phosphorylated by phytochrome that modulates light signaling in Arabidopsis

Plants constantly monitor their light environment in order to grow and develop optimally, in part through use of the phytochromes, which sense red/far-red light. A phytochrome binding protein, PKS1 (phytochrome kinase substrate 1), was identified that is a substrate for light-regulated phytochrome kinase activity in vitro. In vivo experiments suggest that PKS1 is phosphorylated in a phytochrome-dependent manner and negatively regulates phytochrome signaling. The data suggest that phytochromes signal by serine-threonine phosphorylation.

A phytochrome from the fern Adiantum with features of the putative photoreceptor NPH1

In plant photomorphogenesis, it is well accepted that the perception of red/far-red and blue light is mediated by distinct photoreceptor families, i.e., the phytochromes and blue-light photoreceptors, respectively. Here we describe the discovery of a photoreceptor gene from the fern Adiantum that encodes a protein with features of both phytochrome and NPH1, the putative blue-light receptor for second-positive phototropism in seed plants. The fusion of a functional photosensory domain of phytochrome with a nearly full-length NPH1 homolog suggests that this polypeptide could mediate both red/far-red and blue-light responses in Adiantum normally ascribed to distinct photoreceptors.

Eukaryotic phytochromes: light-regulated serine/threonine protein kinases with histidine kinase ancestry

The discovery of cyanobacterial phytochrome histidine kinases, together with the evidence that phytochromes from higher plants display protein kinase activity, bind ATP analogs, and possess C-terminal domains similar to bacterial histidine kinases, has fueled the controversial hypothesis that the eukaryotic phytochrome family of photoreceptors are light-regulated enzymes. Here we demonstrate that purified recombinant phytochromes from a higher plant and a green alga exhibit serine/threonine kinase activity similar to that of phytochrome isolated from dark grown seedlings. Phosphorylation of recombinant oat phytochrome is a light- and chromophore-regulated intramolecular process. Based on comparative protein sequence alignments and biochemical cross-talk experiments with the response regulator substrate of the cyanobacterial phytochrome Cph1, we propose that eukaryotic phytochromes are histidine kinase paralogs with serine/threonine specificity whose enzymatic activity diverged from that of a prokaryotic ancestor after duplication of the transmitter module.

The phytofluors: a new class of fluorescent protein probes

BACKGROUND

Biologically compatible fluorescent protein probes, particularly the self-assembling green fluorescent protein (GFP) from the jellyfish Aequorea victoria, have revolutionized research in cell, molecular and developmental biology because they allow visualization of biochemical events in living cells. Additional fluorescent proteins that could be reconstituted in vivo while extending the useful wavelength range towards the orange and red regions of the light spectrum would increase the range of applications currently available with fluorescent protein probes.

RESULTS

Intensely orange fluorescent adducts, which we designate phytofluors, are spontaneously formed upon incubation of recombinant plant phytochrome apoproteins with phycoerythrobilin, the linear tetrapyrrole precursor of the phycoerythrin chromophore. Phytofluors have large molar absorption coefficients, fluorescence quantum yields greater than 0.7, excellent photostability, stability over a wide range of pH, and can be reconstituted in living plant cells.

CONCLUSIONS

The phytofluors constitute a new class of fluorophore that can potentially be produced upon bilin uptake by any living cell expressing an apophytochrome cDNA. Mutagenesis of the phytochrome apoprotein and/or alteration of the linear tetrapyrrole precursor by chemical synthesis are expected to afford new phytofluors with fluorescence excitation and emission spectra spanning the visible to near-infrared light spectrum.

Phycocyanobilin is the natural precursor of the phytochrome chromophore in the green alga Mesotaenium caldariorum

Compared with phytochromes isolated from etiolated higher plant tissues and a number of lower plant species, the absorption spectrum of phytochrome isolated from the unicellular green alga Mesotaenium caldariorum is blue-shifted (Kidd, D. G., and Lagarias, J. C. (1990) J. Biol. Chem. 265, 7029-7035). The present studies were undertaken to determine whether this blue shift is due to a chromophore other than phytochromobilin or reflects a different protein environment for the phytochromobilin prosthetic group. Using reversed phase high performance liquid chromatography, we show that soluble protein extracts prepared from algal chloroplasts contain the enzyme activities for ferredoxin-dependent conversions of biliverdin IXalpha to (3Z)-phytochromobilin and (3Z)-phytochromobilin to (3Z)-phycocyanobilin. In vitro assembly of recombinant algal apophytochrome was undertaken with (3E)-phytochromobilin and (3E)-phycocyanobilin. The difference spectrum of the (3E)-phycocyanobilin adduct was indistinguishable from that of phytochrome isolated from dark-adapted algal cells, while the (3E)-phytochromobilin adduct displayed red-shifted absorption maxima relative to purified algal phytochrome. These studies indicate that phycocyanobilin is the immediate precursor of the green algal phytochrome chromophore and that phytochromobilin is an intermediate in its biosynthesis in Mesotaenium.

A cyanobacterial phytochrome two-component light sensory system

The biliprotein phytochrome regulates plant growth and developmental responses to the ambient light environment through an unknown mechanism. Biochemical analyses demonstrate that phytochrome is an ancient molecule that evolved from a more compact light sensor in cyanobacteria. The cyanobacterial phytochrome Cph1 is a light-regulated histidine kinase that mediates red, far-red reversible phosphorylation of a small response regulator, Rcp1 (response regulator for cyanobacterial phytochrome), encoded by the adjacent gene, thus implicating protein phosphorylation-dephosphorylation in the initial step of light signal transduction by phytochrome.

Regulation of photomorphogenesis by expression of mammalian biliverdin reductase in transgenic Arabidopsis plants

The photoregulatory activity of the phytochrome photoreceptor requires the synthesis and covalent attachment of the linear tetrapyrrole prosthetic group phytochromobilin. Because the mammalian enzyme biliverdin IX alpha reductase (BVR) is able to functionally inactivate phytochromobilin in vitro, this investigation was undertaken to determine whether BVR expression in transgenic plants would prevent the synthesis of functionally active phytochrome in vivo. Here, we show that plastid-targeted, constitutive expression of BVR in Arabidopsis yields plants that display aberrant photomorphogenesis throughout their life cycle. Photobiological and biochemical analyses of three transgenic BVR lines exhibiting a 25-fold range of BVR expression established that the BVR-dependent phenotypes are light dependent, pleiotropic, and consonant with the loss of multiple phytochrome activities. Chlorophyll accumulation in BVR-expressing transgenic plants was particularly sensitive to increased light fluence rates, which is consistent with an important role for phytochrome in light tolerance. Under blue light, transgenic BVR plants displayed elongated hypocotyls but retained phototropic behavior and the ability to fully deetiolate. Directed BVR expression may prove to be useful for probing the cellular and developmental basis of phytochrome-mediated responses and for selective control of individual aspects of light-mediated plant growth and development.

Regulation of photomorphogenesis by expression of mammalian biliverdin reductase in transgenic Arabidopsis plants

The photoregulatory activity of the phytochrome photoreceptor requires the synthesis and covalent attachment of the linear tetrapyrrole prosthetic group phytochromobilin. Because the mammalian enzyme biliverdin IX alpha reductase (BVR) is able to functionally inactivate phytochromobilin in vitro, this investigation was undertaken to determine whether BVR expression in transgenic plants would prevent the synthesis of functionally active phytochrome in vivo. Here, we show that plastid-targeted, constitutive expression of BVR in Arabidopsis yields plants that display aberrant photomorphogenesis throughout their life cycle. Photobiological and biochemical analyses of three transgenic BVR lines exhibiting a 25-fold range of BVR expression established that the BVR-dependent phenotypes are light dependent, pleiotropic, and consonant with the loss of multiple phytochrome activities. Chlorophyll accumulation in BVR-expressing transgenic plants was particularly sensitive to increased light fluence rates, which is consistent with an important role for phytochrome in light tolerance. Under blue light, transgenic BVR plants displayed elongated hypocotyls but retained phototropic behavior and the ability to fully deetiolate. Directed BVR expression may prove to be useful for probing the cellular and developmental basis of phytochrome-mediated responses and for selective control of individual aspects of light-mediated plant growth and development.

Purification and characterization of recombinant affinity peptide-tagged oat phytochrome A

Full-length Avena sativa (oat) phytochrome A (ASPHYA) was expressed in the yeast Saccharomyces cerevisiae and purified to apparent homogeneity. Expression of an ASPHYA cDNA that encoded the full-length photoreceptor with a 15 amino acid 'strep-tag' peptide at its C-terminus produced a single polypeptide with a molecular mass of 124 kDa. This strep-tagged polypeptide (ASPHYA-ST) bound tightly to streptavidin agarose and was selectively eluted using diaminobiotin, with a chromatographic efficiency of 45%. Incubation of ASPHYA-ST with phytochromobilin (P phi B) and the unnatural chromophore precursors, phycocyanobilin (PCB) and phycoerythrobilin (PEB), produced covalent adducts that were similarly affinity purified. Both P phi B and PCB adducts of ASPHYA-ST were photoactive--the P phi B adduct displaying spectrophotometric properties nearly indistinguishable from those of the native photoreceptor, and the PCB adduct exhibiting blue-shifted absorption maxima. Although the PEB adduct of ASPHYA-ST was photochemically inactive, it was intensely fluorescent with an excitation maximum at 576 nm and emission maxima at 586 nm. The superimposability of its absorption and fluorescence excitation spectra established that a single biliprotein species was responsible for fluorescence from the adduct produced when ASPHYA-ST was incubated with PEB. Steric exclusion HPLC also confirmed that ASPHYA-ST and its three bilin adducts were homodimers, as has been established for phytochrome A isolated from natural sources. The ability to express and purify recombinant phytochromes with biochemical properties very similar to those of the native molecule should facilitate detailed structural analysis of this important class of photoreceptors.

Resonance raman analysis of chromophore structure in the lumi-R photoproduct of phytochrome

Resonance Raman vibrational spectra of the Pr, lumi-R, and Pfr forms of phytochrome have been obtained using low-temperature trapping and room temperature flow techniques in conjunction with shifted-excitation Raman difference spectroscopy (SERDS). The Pr to lumi-R photoconversion exhibits a thermal barrier and is completely blocked at 30 K, indicating that thermally assisted protein relaxation is necessary for the primary photochemistry. When Pr is converted to lumi-R, new bands appear in the C = C and C = N stretching regions at 1651, 1636, 1590, and 1569 cm-1, indicating that a significant structural change of the chromophore has occurred. The photoconversion also results in an 18 cm-1 decrease in the N-H rocking band in lumi-R. Normal mode calculations correlate this frequency drop with a change in the geometry of the C15 methine bridge of the phytochromobilin chromophore. Additionally, a C = N stretching mode marker band shifts from 1576 cm-1 in Pr to 1569 cm-1 in lumi-R and to 1552 cm-1 in Pfr. Normal mode calculations show that the frequency drop of this band in the lumi-R-->Pfr interconversion is an indication of a C14-C15 syn-->anti conformational change. Moderately intense hydrogen out-of-plane modes that occur at 805 cm-1 in Pr shift to 829 and 847 cm-1 upon photoconversion to lumi-R and are replaced by a very intense mode at 814 cm-1 in Pfr. These observations indicate that the C and D rings of the chromophore in Pr and lumi-R are moderately planar but that they become highly distorted in Pfr. This information suggests that the primary photochemistry in phytochrome is a Z-->E isomerization of the C15 = C16 bond of Pr giving lumi-R. This is followed by a thermal syn-->anti C14-C15 conformational relaxation to form Pfr. A four-state model is presented to explain the chromophore structural changes in Pr, lumi-R, and Pfr that uses hydrogen bonding to the surrounding protein to stabilize the high-energy Pfr C15 = C16, C14-C15, E,anti chromophore structure. This implicates an anchor and release mechanism between the chromophore and protein that might lead to altered biological signaling in the plant.

The methylotrophic yeast Pichia pastoris synthesizes a functionally active chromophore precursor of the plant photoreceptor phytochrome

Induction of the expression of an algal phytochrome cDNA in the methylotrophic yeast Pichia pastoris led to time-dependent formation of photoactive holophytochrome without the addition of exogenous bilins. Both in vivo and in vitro difference spectra of this phytochromic species are very similar to those of higher plant phytochrome A, supporting the conclusion that this species possesses a phytochromobilin prosthetic group. Zinc blot analyses confirm that a bilin chromophore is covalently bound to the algal phytochrome apoprotein. The hypothesis that P. pastoris contains phytochromobilin synthase, the enzyme that converts biliverdin IX alpha to phytochromobilin, was also addressed in this study. Soluble extracts from P. pastoris were able to convert biliverdin to a bilin pigment, which produced a native difference spectrum upon assembly with oat apophytochrome A. HPLC analyses confirm that biliverdin is converted to both 3E- and 3Z-isomers of phytochromobilin. These investigations demonstrate that the ability to synthesize phytochromobilin is not restricted to photosynthetic organisms and support the hypothesis of a more widespread distribution of the phytochrome photoreceptor.

Atypical phytochrome gene structure in the green alga Mesotaenium caldariorum

The phytochrome photoreceptor in the green alga Mesotaenium caldariorum is encoded by a small family of highly related genes. DNA sequence analysis of two of the algal phytochrome genes indicates an atypical gene structure with numerous long introns. The two genes, termed mesphy1a and mesphy1b, encode polypeptides which differ by one amino acid in the region of overlap that was sequenced. RT-PCR studies have established the intron-exon junctions of both genes and show that both are expressed. RNA blot analysis indicates a single transcript of ca. 4.1 kb in length. The deduced amino acid sequence of the mesphy1b gene reveals that the photoreceptor consists of 1142 amino acids, with an overall structure similar to other phytochromes. Phylogenetic analyses indicate that the algal phytochrome falls into a distinct subfamily with other lower plant phytochromes. Profile analysis of an internal repeat found within the central hinge region of the phytochrome polypeptide indicates an evolutionary relatedness to the photoactive yellow protein from the purple bacterium Ectothiorhodospira halophila, to several bacterial sensor kinase family members, and to a family of eukaryotic regulatory proteins which includes the period clock (per) and single-minded (sim) gene products of Drosophila. Since mutations which alter phytochrome activity cluster within the region delimited by these direct repeats (P.H. Quail et al., Science 268 (1995): 675-680), this conserved motif may play an important role in the signal transducing function of these disparate protein families.

Continuous fluorescence assay of phytochrome assembly in vitro

Incubation of recombinant apophytochrome with the phycobiliprotein chromophore precursor phycoerythrobilin produces a covalent adduct that exhibits a fluorescence excitation maximum at 576 nm and an emission maximum at 586 nm. Using these fluorescence parameters, we have developed a kinetic assay for quantitative analysis of the assembly of the plant photoreceptor phytochrome in real time. Kinetic measurements performed with different phycoerythrobilin concentrations confirm that bilin attachment to apophytochrome involves two steps, an initial formation of a reversible non-covalent complex followed by thioether bond formation. The kinetic constants for both steps of phycoerythrobilin attachment to apophytochrome were estimated with this assay. Methodology for determining the kinetic constants for the assembly of both the natural phytochrome chromophore precursor, phytochromobilin, and the analog phycocyanobilin is also described. Since the latter two bilins yield covalent, nonfluorescent adducts with apophytochrome, their co-incubation with phycoerythrobilin reduces the rate of formation of the fluorescent phycoerythrobilin adduct in an irreversible, competitive manner. Competition experiments were also performed with biliverdin, a structurally related bilin which does not form a covalent adduct with apophytochrome. Such measurements show that biliverdin reversibly binds to apophytochrome with a submicromolar binding constant, an affinity which is very similar to that of phytochromobilin. The utility of this fluorescence assay for identification of novel inhibitors of phytochrome assembly and for characterization of the structural features of both bilin and apophytochrome necessary for photoreceptor assembly is discussed.

(3Z)- and (3E)-phytochromobilin are intermediates in the biosynthesis of the phytochrome chromophore

Using a high performance liquid chromatography (HPLC)-based assay, we have demonstrated that isolated oat etioplasts convert the linear tetrapyrrole biliverdin IX alpha to (3E)-phytochromobilin, the proposed precursor of the chromophore of the plant photoreceptor phytochrome. In addition to (3E)-phytochromobilin, the synthesis of a second phytochromobilin was detected by its ability to functionally assemble with recombinant oat apophytochrome A. The structure of this new pigment has been determined to be the 3Z isomer of phytochromobilin by absorption and 1H NMR spectroscopy. Like (3E)-phytochromobilin, assembly of HPLC-purified (3Z)-phytochromobilin with apophytochrome yielded a holoprotein that is spectrally indistinguishable from native oat phytochrome A. However, the postchromatographic conversion of (3Z)- to (3E)-phytochromobilin appears to be responsible for this result. Kinetic HPLC analyses have demonstrated that (3Z)-phytochromobilin is synthesized prior to the 3E isomer by oat etioplasts. We therefore propose that (3Z)-phytochromobilin is the immediate product of biliverdin IX alpha reduction by the enzyme phytochromobilin synthase. This implicates the presence of an isomerase that catalyzes the conversion of (3Z)- to (3E)-phytochromobilin, the immediate precursor of the phytochrome A chromophore.

Phytochrome assembly in living cells of the yeast Saccharomyces cerevisiae

The biological activity of the plant photoreceptor phytochrome requires the specific association of a linear tetrapyrrole prosthetic group with a large apoprotein. As an initial step to develop an in vivo assay system for structure-function analysis of the phytochrome photoreceptor, we undertook experiments to reconstitute holophytochrome in the yeast Saccharomyces cerevisiae. Here we show that yeast cells expressing recombinant oat apophytochrome A can take up exogenous linear tetrapyrroles, and, in a time-dependent manner, these pigments combine with the apoprotein to form photoactive holophytochrome in situ. Cell viability measurements indicate that holophytochrome assembly occurs in living cells. Unlike phytochrome A in higher plant tissue, which is rapidly degraded upon photoactivation, the reconstituted photoreceptor appears to be light stable in yeast. Reconstitution of photoactive phytochrome in yeast cells should enable us to exploit the power of yeast genetics for structure-function dissection of this important plant photoreceptor.

Inactivation of phytochrome- and phycobiliprotein-chromophore precursors by rat liver biliverdin reductase

The phytochrome chromophore precursor, 3E-phytochromobilin, and the phycobiliprotein chromophore precursors, 3E-phycocyanobilin and 3E-phycoerythrobilin, are enzymatically converted to novel rubinoid products by purified rat liver biliverdin reductase. Phytochromobilin and phycocyanobilin are particularly good substrates for biliverdin reductase with Km and Vmax values very similar to those of the natural substrate, biliverdin IX alpha. Phycoerythrobilin is the least preferred of the three bilin substrates. 1H NMR spectroscopy of phycocyanorubin, the product of phycocyanobilin catalysis by biliverdin reductase, and comparison of absorption spectra of all three rubinoid products reveal that the C10 methine bridge is selectively reduced by biliverdin reductase without altering the A-ring ethylidene substituent. In vitro phytochrome assembly experiments demonstrate that the phytorubin products do not form photoactive adducts with recombinant apophytochrome. These results suggest that ectopic expression of biliverdin reductase in plants will prevent assembly of the functional photoreceptor and thus will potentially alter light-mediated plant growth and development.

Phytochrome levels in the green alga Mesotaenium caldariorum are light regulated

Experiments undertaken in this investigation examine the influence of light on the levels of phytochrome in the green alga Mesotaenium caldariorum and also provide partial protein sequence of the algal phytochrome. Immunochemical and spectrophotometric measurements reveal that phytochrome levels increase nearly 4-fold upon transfer of light-grown algal cells to total darkness during a 6- to 8-d adaptation period. Within 24 h after return to continuous illumination, the level of phytochrome in dark-adapted cells has decreased to that found in light-grown cells. Red or far-red light experiments show that both effects of light, phytochrome accumulation during dark adaptation and light-dependent decrease of phytochrome, do not depend on the form of the phytochrome photoreceptor (i.e. far-red absorbing or red absorbing) present in the algal cell. The light-dependent reduction of phytochrome in dark-adapted cells is inhibited by the photosynthetic electron transport inhibitor 3-(3,4-dichlorophenyl)-1,1-dimethyl urea, suggesting that this light effect is mediated by photosynthesis. Microsequence analyses of internal peptides indicate that algal phytochrome purified from dark-adapted cells shares the greatest sequence identity with phytochrome from the fern Selaginella (74%). Compared with higher plant photoreceptors, Mesotaenium phytochrome appears to be more closely related to phyB gene products (i.e. 62 and 63% average sequence identity) than to phyA gene products (i.e. 50 and 53% average sequence identity). Because light regulation and the structure of Mesotaenium phytochrome do not conform with either type I (light-labile) or type II (light-stable) phytochromes from higher plants, these results support the hypothesis that the lower green plant photoreceptors represent a distinct class of phytochrome.

Phytochrome assembly. Defining chromophore structural requirements for covalent attachment and photoreversibility

Assembly of holophytochrome in the plant cell requires covalent attachment of the linear tetrapyrrole chromophore precursor, phytochromobilin, to a unique cysteine in the nascent apoprotein. In this investigation we compare chromophore analogs with the natural chromophore precursor for their ability to attach covalently to recombinant oat apophytochrome and to form photoactive holoproteins. Ethylidene-containing analogs readily form covalent adducts with apophytochrome, whereas chromophores lacking this double bond are poor substrates for attachment. Kinetic measurements establish that although the chromophore binding site on apophytochrome is best tailored to phytochromobilin, apophytochrome will accommodate the two analogs with modified D-rings, phycocyanobilin and phycoerythrobilin. The phycocyanobilin-apophytochrome adduct is photoactive and undergoes a light-induced protein conformational change similar to the native holoprotein. By contrast, the phycoerythrobilin adduct is locked into a photochemically inactive protein conformation that is similar to the red light-absorbing Pr form of phytochrome. These results support the hypothesis that the photoconversion from Pr to Pfr, the far red light- absorbing form of phytochrome, involves the photoisomerization of the C15 double bond. Knowledge gained from these studies provides impetus for rational design of chromophore analogs whose insertion into apophytochrome should elicit profound changes in light-mediated plant growth and development.

Phytochrome assembly. The structure and biological activity of 2(R),3(E)-phytochromobilin derived from phycobiliproteins

The unicellular rhodophyte, Porphyridium cruentum, and the filamentous cyanobacterium, Calothrix sp. PCC 7601, contain phycobiliproteins that have covalently bound phycobilin chromophores. Overnight incubation of solvent-extracted cells at 40 degrees C with methanol liberates free phycobilins that are derived from the protein-bound bilins by methanolytic cleavage of the thioether linkages between bilin and apoprotein. Two of the free bilins were identified as 3(E)-phycocyanobilin and 3(E)-phycoerythrombilin by comparative spectrophotometry and high pressure liquid chromatography. Methanolysis also yields a third bilin free acid whose absorption and 1H NMR spectra support the assignment of the 3(E)-phytochromobilin structure. This novel bilin is the major pigment isolated from cells that are pre-extracted with acetone-containing solvents. Since phytochrome- or phytochromobilin-containing proteins are not present in either organism, the 3(E)-phytochromobilin must arise by oxidation of phycobilin chromophores. This pigment is not obtained by similar treatment of a cyanobacterium and a rhodophyte that lack phycoerythrin. Therefore, 3(E)-phytochromobilin appears to be derived from phycoerythrobilin-containing proteins. Comparative CD spectroscopy of 3(E)-phytochrombilin and 3(E)-phycocyanobilin suggests that the two bilins share the R stereochemistry at the 2-position in the reduced pyrrole ring. Incubation of 2(R),3(E)-phytochromobilin with recombinant oat apophytochrome yields a covalent bilin adduct that is photoactive and spectrally indistinguishable from native oat phytochrome isolated from etiolated seedlings. These results establish that the phycobiliprotein-derived 2(R),3(E)-phytochromobilin is a biologically active phytochrome chromophore precursor.

Expression and assembly of spectrally active recombinant holophytochrome

To develop an in vitro phytochrome assembly system, we have expressed an oat phytochrome cDNA in both the yeast Saccharomyces cerevisiae and the bacterium Escherichia coli. Analysis of soluble protein extracts showed that the recombinant apophytochromes were full-length and capable of covalently attaching the phytochrome chromophore analogue phycocyanobilin. Difference spectra indicated that in vitro-assembled holophytochrome species were photoreversible; however, maxima and minima difference absorption values were blue-shifted relative to those of the native photoreceptor. Extracts containing the recombinant apophytochromes were also incubated with phytochromobilin, the natural chromophore synthesized from biliverdin by cucumber etioplast preparations. In these experiments, the difference spectrum obtained was identical to that of native oat holophytochrome. These results suggest that the recombinant apophytochromes adopt a structure similar to that of the apoprotein biosynthesized in vivo. ELISAs were used to quantitate phytochrome expression levels in both yeast and E. coli extracts. These measurements show that 62-75% of the phytochrome apoprotein in the soluble protein extract was competent to assemble with bilins to form spectrally active holophytochrome.

Holophytochrome assembly. Coupled assay for phytochromobilin synthase in organello

Utilizing an in vitro coupled assay system, we show that isolated plastids from cucumber cotyledons convert the linear tetrapyrrole biliverdin IX alpha to the free phytochrome chromophore, phytochromobilin, which assembles with oat apophytochrome to yield photoactive holoprotein. The spectral properties of this synthetic phytochrome are indistinguishable from those of the natural photoreceptor. The plastid-dependent biliverdin conversion activity is strongly stimulated by both NADPH and ATP. Substitution of the nonnatural XIII alpha isomer of biliverdin for the IX alpha isomer affords a synthetic holophytochrome adduct with blue-shifted difference spectra. These results, together with experiments using boiled plastids, indicate that phytochromobilin synthesis from biliverdin is enzyme-mediated. Experiments where NADPH (and ATP) levels in intact developing chloroplasts are manipulated by feeding the metabolites 3-phosphoglycerate, dihydroxyacetone phosphate, and glucose 6-phosphate or by illumination with white light, support the hypothesis that the enzyme that accomplishes this conversion, phytochromobilin synthase, is plastid-localized. It is therefore likely that all of the enzymes of the phytochrome chromophore biosynthetic pathway reside in the plastid.

Resonance Raman analysis of the Pr and Pfr forms of phytochrome

Resonance Raman vibrational spectra of the Pr and Pfr forms of oat phytochrome have been obtained at room temperature. When Pr is converted to Pfr, new bands appear in the C = C and C = N stretching region at 1622, 1599, and 1552 cm-1, indicating that a major structural change of the chromophore has occurred. The Pr to Pfr conversion results in an 11 cm-1 lowering of the N-H rocking band from 1323 to 1312 cm-1. Normal mode calculations correlate this frequency drop with a Z----E isomerization about the C15 = C16 bond. A line at 803 cm-1 in Pr is replaced by an unusually intense mode at 814 cm-1 in Pfr. Calculations on model tetrapyrrole chromophores suggest that these low-wavenumber modes are hydrogen out-of-plane (HOOP) wagging vibrations of the bridging C15 methine hydrogen and that both the intensity and frequency of the C15 HOOP mode are sensitive to the geometry around the C14-C15 and C15 = C16 bonds. The large intensity of the 814-cm-1 mode in Pfr indicates that the chromophore is highly distorted from planarity around the C15 methine bridge. If the Pr----Pfr conversion does involve a C15 = C16 Z----E isomerization, then the intensity of the C15 HOOP mode in Pfr argues that the chromophore has an E,anti conformation. On the basis of a comparison with the vibrational calculations, the low frequency (803 cm-1) and the reduced intensity of the C15 HOOP mode in Pr suggest that the chromophore in Pr adopts the C15-Z,syn conformation.

Calcium Transport in the Green Alga Mesotaenium caldariorum: Preliminary Characterization and Subcellular Distribution

The subcellular localization and biochemical characterization of calcium transport were studied in the unicellular green alga Mesotaenium caldariorum. Membrane fractions prepared by osmotic lysis of Mesotaenium protoplasts exhibit high rates of ATP-dependent calcium uptake. Sucrose gradient centrifugation separates two pools of activity, which display specific activities for calcium transport as high as 15 nanomoles Ca(2+) per minute per milligram of protein. Marker enzyme analysis shows that this dual distribution of calcium transport activity is similar to that of vanadate-insensitive ATPase and pyrophosphatase, activities considered to be associated with the tonoplast. Plasma membranes, endoplasmic reticulum vesicles, mitochondrial membranes, and thylakoids band at higher densities than either calcium transport fraction. Both pools of ATP-dependent calcium uptake contain two components which are not separable on sucrose gradients but can be distinguished on the basis of inhibitor sensitivity. One component is inhibited by nigericin or trimethyltin chloride (I(50) values of 3 nanomolar and 4 micromolar, respectively), while the other component is vanadate sensitive (I(50) of 25 micromolar). These results suggest that direct Ca(2+) transport and Ca(2+)/H(+) antiport activities are present in both sucrose gradient fractions.

Phytochrome from the green alga Mesotaenium caldariorum. Purification and preliminary characterization

A method to purify the phytochrome photoreceptor from the unicellular green alga Mesotaenium caldariorum is presented. Preparative scale formation of algal protoplasts and controlled osmotic cell lysis have permitted separation of intact organelles from the phytochrome-enriched soluble protein fraction. We have utilized the observation that red light-absorbing (Pr) and far-red light-absorbing (Pfr) forms of phytochrome are differentially retained on an anion exchange matrix to purify M. caldariorum phytochrome to apparent homogeneity. M. caldariorum phytochrome preparations with A650/A280 ratios greater than 0.78 exhibit a single 120-kDa band on silver-stained sodium dodecyl sulfate-polyacrylamide gels. Immunoblot analyses using a cross-reactive pea phytochrome monoclonal antibody reveal that 1) the 120-kDa band represents the full-length polypeptide, 2) phytochrome is predominantly localized in the algal cytoplasm, and 3) there are 150,000-250,000 phytochrome molecules/cell. Steric exclusion high pressure liquid chromatography analysis under nondenaturing conditions indicates that M. caldariorum phytochrome has an apparent mass of 355 kDa. The absorption maxima for Pr and Pfr are 650 and 722 nm, respectively. Both are blue-shifted compared with those of phytochromes from dark-grown angiosperm tissue. The molar absorption coefficient for Pr at 650 nm is 86,800 +/- 2800 liter mol-1 cm-1, which is lower than that of higher plant phytochromes. The significance of the similarities and differences of the molecular properties of phytochromes from M. caldariorum and higher plant sources is discussed.

Phosphopeptide mapping of Avena phytochrome phosphorylated by protein kinases in vitro

We previously demonstrated that protein kinases are useful probes of conformational changes that occur upon photoconversion of phytochrome [Wong, Y.-S., Cheng, H.-C., Walsh, D. A., & Lagarias, J. C. (1986) J. Biol. Chem. 261, 12089-12097]. Here we present phosphopeptide analyses of oat phytochrome phosphorylated by three mammalian protein kinases and by a polycation-stimulated, phytochrome-associated protein kinase. Phosphorylation of the Pr form by the cAMP-dependent protein kinase occurs predominantly on Ser17 while Ser598 is the preferred phosphorylation site on Pfr. The cGMP-dependent and Ca2(+)-activated, phospholipid-dependent protein kinases, which phosphorylate only the Pr form of phytochrome, recognize the same region on the phytochrome polypeptide as the cAMP-dependent protein kinase. Polycation-stimulated phytochrome phosphorylation reveals that, in contrast to the mammalian enzymes, the plant kinase recognizes the serine-rich, blocked N-terminus of phytochrome. The potential regulatory role of phytochrome phosphorylation, particularly in the structurally conserved serine/threonine-rich N-terminal region of the phytochrome polypeptide, is suggested by these results.

Properties of a polycation-stimulated protein kinase associated with purified Avena phytochrome

ATP-dependent polycation-stimulated phosphorylation of highly purified phytochrome preparations from etiolated Avena seedlings has been reported previously (Y-S Wong, H-C Cheng, DA Walsh, JC Lagarias [1986] J Biol Chem 261: 12089-12097). In this study, we present a more detailed description of the properties of this protein kinase based on the analysis of over 30 different Avena phytochrome preparations. ATP-dependent phosphorylation of phytochrome was strongly stimulated by a wide range of polycationic molecules, including synthetic and natural polypeptides as well as nonpeptide cationic polymers. Many of the compounds known to stimulate other known protein kinases (i.e., cyclic nucleotides, Ca(2+), calmodulin, diacylglycerol, phospholipids) were either inhibitory or nonstimulatory. Among the polycations, histone H1, polylysine, and polybrene were the most effective, giving average stimulations of four- to sevenfold. Polycation-stimulated protein phosphorylation was inhibited by elevated ionic strength; of the salts examined, magnesium pyrophosphate was a particularly potent inhibitor of the kinase activity. MgATP was preferred as the phosphoryl donor to either MgGTP or magnesium pyrophosphate. The K(m) for MgATP was estimated to be 30 micromolar when histone H1 was used as a protein substrate. The Pr form of phytochrome was always a better substrate than the Pfr form regardless of the polycation present. Polylysine-stimulated, phytochrome(preparation)-dependent phosphorylation of purified maize phosphoenolpyruvate carboxylase was observed, as well as phosphorylation of a number of polypeptides in crude soluble protein extracts from etiolated Avena seedlings.

Formation of a photoreversible phycocyanobilin-apophytochrome adduct in vitro

Avena seedlings grown in the presence of the plant tetrapyrrole synthesis inhibitor 4-amino-5-hexynoic acid contain less than 10% of the spectrally detectable phytochrome levels found in untreated seedlings, but continue to accumulate phytochrome apoprotein (Elich, T. D., and Lagarias, J. C. (1988) Plant Physiol. 88, 747-751). Using such tetrapyrrole-deficient seedlings, we have previously reported that phycocyanobilin, the cleaved prosthetic group of C-phycocyanin, can be incorporated into phytochrome in vivo to yield spectrally active holoprotein (Elich, T. D., McDonagh, A. F., Palma, L. A., and Lagarias, J. C. (1988) J. Biol. Chem. 264, 183-189). Here we show that addition of phycocyanobilin to soluble extracts of inhibitor-treated seedlings results in a rapid increase in spectrally active phytochrome holoprotein. The newly formed photoactive species displays a blue-shifted absorbance difference spectrum similar to that observed in the previous in vivo studies. The increase in spectral activity is consistent with conversion of all of the preexisting phytochrome apoprotein to functionally active holoprotein. The formation of a covalent phycocyanobilin-apophytochrome adduct is shown by an increase in Zn2+-dependent bilin fluorescence of the phytochrome polypeptide. A photoreversible, covalent adduct with a similar optical spectrum also forms when immunopurified apophytochrome is incubated with phycocyanobilin. ATP, reduced pyridine nucleotides, or other cofactors are not required for adduct formation. When biliverdin IX alpha is substituted for phycocyanobilin, no spectrally active covalent adduct is produced. These results indicate that an A-ring ethylidene-containing bilatriene is required for post-translational covalent attachment of bilin to apophytochrome and that apophytochrome may be the bilin C-S lyase which catalyzes bilin attachment.

Phytochrome chromophore biosynthesis. Treatment of tetrapyrrole-deficient Avena explants with natural and non-natural bilatrienes leads to formation of spectrally active holoproteins

Etiolated Avena seedlings grown in the presence of 4-amino-5-hexynoic acid, an inhibitor of 5-aminolevulinic acid synthesis in plants, contain less than 10% of the spectrally detectable levels of phytochrome found in untreated seedlings (Elich, T.D., and Lagarias, J.C. (1988) Plant Physiol. 88, 747-751). In this study, incubation of explants from such seedlings with [14C]biliverdin IX alpha led to rapid covalent incorporation of radiolabel into a single 124-kDa polypeptide in soluble protein extracts. Immunoprecipitation experiments confirmed that this protein was phytochrome. Parallel experiments were performed with four unlabeled linear tetrapyrroles, the naturally occurring biliverdin IX alpha isomer, two non-natural isomers, biliverdin XIII alpha and biliverdin III alpha, and phycocyanobilin-the cleaved prosthetic group of the light-harvesting antenna protein C-phycocyanin. In all cases, except for the III alpha isomer of biliverdin, a time-dependent recovery of photoreversible phytochrome was observed. The newly formed phytochrome obtained after incubation with biliverdin IX alpha exhibited spectral characteristics identical with those of the native protein. In contrast, the spectral properties of phytochromes formed during incubation with biliverdin XIII alpha and phycocyanobilin differed significantly from those of the native chromoprotein. These results indicate that biliverdin IX alpha is an intermediate in the biosynthesis of the phytochrome chromophore and that phytochromes with prosthetic groups derived from bilatrienes having non-natural D-ring substituents are photochromic.

Mapping of antigenic domains on phytochrome from etiolated Avena sativa L. by immunoblot analysis of proteolytically derived peptides

Several monoclonal antibodies to phytochrome that interact with putative functionally important domains have been previously identified. The locations of some of these domains are determined here by epitope mapping experiments that utilize immunoblot analyses of proteolytically degraded phytochrome. Seven independent epitopes are identified. An epitope that is recognized by monoclonal antibody Oat-25 is confirmed to be wholly located near the N terminus of phytochrome. This domain undergoes a conformational change when phytochrome is interconverted between its red- and far-red-absorbing forms and is recognized by Oat-25 better in the red-absorbing form. A second domain that also undergoes a photointerconvertible conformation change and that contains the epitope for Oat-16 is localized near the site of chromophore attachment, which is about 36 kDa from the N terminus. A third domain, which contains the most highly conserved epitope on phytochrome that has so far been identified, is recognized by Pea-25 and is located about 85 kDa from the N terminus. Other epitopes and their approximate distances from the N terminus are those recognized by Oat-22 (36 kDa), Oat-13 (65 kDa), and Oat-8 and Oat-28 (70-75 kDa). Even though epitopes for Oat-16 and Oat-22, as well as for Oat-8 and Oat-28, are close together, competitive binding assays indicate that they are different. Immunoblot analyses also indicate that the epitope for Oat-28 is further from the N terminus of phytochrome than is that for Oat-8.

4-amino-5-hexynoic Acid-a potent inhibitor of tetrapyrrole biosynthesis in plants

4-Amino-5-hexynoic acid, a suicide inactivator of the mammalian pyridoxal phosphate-dependent 4-aminobutyric acid:2-oxoglutaric acid aminotransferase, inhibits phytochrome and chlorophyll synthesis in developing oat (Avena sativa L.), corn (Zea mays L.), pea (Pisum sativum L.), and cucumber (Cucumis sativus L.) seedlings. In Avena and Cucumis seedlings, respectively, inhibition of phytochrome and chlorophyll accumulation by 4-amino-5-hexynoic acid can be significantly reversed by application of 5-aminolevulinic acid. These results indicate that 4-amino-5-hexynoic acid inhibits the synthesis of 5-aminolevulinic acid in plants.

Exclusive A-ring linkage for singly attached phycocyanobilins and phycoerythrobilins in phycobiliproteins. Absence of singly D-ring-linked bilins

Previous spectroscopic studies on the phycocyanobilin-containing peptide beta-2T from Synechococcus sp. 6301 C-phycocyanin and the phycoerythrobilin-containing peptide beta-2TP from Porphyridium cruentum B-phycoerythrin indicated a different single thioether mode of attachment, postulated to be through the D-ring of the tetrapyrrole, in contrast to the A-ring linkage established for the other singly linked bilins in these proteins (Bishop, J.E., Lagarias, J.C., Nagy, J. O., Schoenleber, R.W., Rapoport, H., Klotz, A.V., and Glazer, A.N. (1986) J. Biol. Chem. 261, 6790-6796; Klotz, A.V., Glazer, A.N., Bishop, J.E., Nagy, J.O., and Rapoport, H. (1986) J. Biol. Chem. 261, 6797-6805). The crystal structure of Agmenellum quadruplicatum C-phycocyanin at 2.5-A resolution (Schirmer, T., Bode, W., and Huber, R. (1987) J. Mol. Biol., 196, 677-695) supports an A-ring linkage for all three phycocyanobilins. Consequently we have re-evaluated our proposed structural assignments by further 1H NMR studies. Two-dimensional homonuclear correlated and nuclear Overhauser enhancement spectroscopic data presented here show that all three bilins in Synechococcus 6301 C-phycocyanin are attached solely through the A-ring, complementary to the crystallographic data. The evidence from the NMR data for all bilin peptides examined includes the dipoledipole interactions of the 5-H with the 3-H, 3'-H, and a pyrrole methyl group (7-CH3); the corresponding interactions would not be possible in a D-ring-linked bilin. The 5-H also consistently exhibits allylic J-coupling to the 3-H, supporting A-ring linkage assignment. These data are inconsistent with the alternative D-ring linkage assignment since this would involve J-coupling through five bonds. Examination of the phycoerythrobilin beta-2 position in B-phycoerythrin also reveals an A-ring type of attachment by similar criteria. We conclude that all singly linked bilins are attached through the A-ring.