Arabidopsis protochlorophyllide oxidoreductase A (PORA) restores bulk chlorophyll synthesis and normal development to a porB porC double mutant

In angiosperms the strictly light-dependent reduction of protochlorophyllide to chlorophyllide is catalyzed by NADPH:protochlorophyllide oxidoreductase (POR). The Arabidopsis thaliana genome encodes three structurally related but differentially regulated POR genes, PORA, PORB and PORC. PORA is expressed primarily early in development—during etiolation, germination and greening. In contrast, PORB and PORC are not only expressed during seedling development but also throughout the later life of the plant, during which they are responsible for bulk chlorophyll synthesis. The Arabidopsis porB-1 porC-1 mutant displays a severe xantha (highly chlorophyll-deficient) phenotype characterized by smaller prolamellar bodies in etioplasts and decreased thylakoid stacking in chloroplasts. Here we have demonstrated the ability of an ectopic PORA overexpression construct to restore prolamellar body formation in the porB-1 porC-1 double mutant background. In response to illumination, light-dependent chlorophyll production, thylakoid stacking and photomorphogenesis are also restored in PORA-overexpressing porB-1 porC-1 seedlings and adult plants. An Arabidopsis porB-1 porC-1 double mutant can therefore be functionally rescued by the addition of ectopically expressed PORA, which suffices in the absence of either PORB or PORC to direct bulk chlorophyll synthesis and normal plant development.     

Assembly of NADPH:protochlorophyllide oxidoreductase complex is needed for effective greening of barley seedlings

NADPH:protochlorophyllide (Pchlide) oxidoreductase (POR) is the key enzyme in the light-induced greening of higher plants. A unique light-harvesting POR:Pchlide complexes (LHPP) has been found in barley etioplasts, but not in other plant species. Why PORs from barley, but not from other plants, can form LHPP? And its function is not well understood. We modeled the barley and Arabidopsis POR proteins and compared molecular surface. The results confirm the idea that barley PORA can form a five-unit oligomer that interacts with a single PORB. Chemical treatment experiments indicated that POR complex may be formed by dithiol oxidation of cysteines of two adjacent proteins. We further showed that LHPP assembly was needed for barley POR functions and seedling greening. On the contrary, Arabidopsis POR proteins only formed dimers, which were not related to the functions or the greening. Finally, POR complex assembly (including LHPP and POR dimers) did not affect the formation of prolamellar bodies (PLBs) that function for efficient capture of light energy for photo conversion in etioplasts.     

ADP/ATP and protein phosphorylation dependence of phototransformable protochlorophyllide in isolated etioplast membranes

The effects of modulated ADP/ATP and NADPH/NADP⁺ ratios, and of protein kinase inhibitors, on the in vitro reformation of phototransformable protochlorophyllide, i.e. the aggregated ternary complexes between NADPH, protochlorophyllide, and NADPH-protochlorophyllide oxidoreductase (POR, EC 1.3.1.33), in etioplast membranes isolated from dark-grown wheat (Triticum aestivum) were investigated. Low temperature fluorescence emission spectra (–196 °C) were used to determine the state of the pigments. The presence of spectral intermediates of protochlorophyllide and the reformation of phototransformable protochlorophyllide were reduced at high ATP, but favoured by high ADP. Increased ADP level partly prevented the chlorophyllide blue-shift. The protein kinase inhibitor K252a prevented reformation of phototransformable protochlorophyllide without showing any effect on the chlorophyllide blue-shift. Addition of NADPH did not overcome the inhibition. The results indicate that protein phosphorylation plays a role in the conversion of the non-phototransformable protochlorophyllide to POR-associated phototransformable protochlorophyllide. The possible presence of a plastid ADP-dependent kinase, the activity of which favours the formation of PLBs, is discussed. Reversible protein phosphorylation is suggested as a regulatory mechanism in the prolamellar body formation and its light-dependent dispersal by affecting the membrane association of POR. By the presence of a high concentration of phototransformable protochlorophyllide, prolamellar bodies can act as light sensors for plastid development. The modulation of plastid protein kinase and protein phosphatase activities by the NADPH/NADP⁺ ratio is suggested. This revised version was published online in June 2006 with corrections to the Cover Date.     

A twin-track approach has optimized proton and hydride transfer by dynamically coupled tunneling during the evolution of protochlorophyllide oxidoreductase

Protein dynamics are crucial for realizing the catalytic power of enzymes, but how enzymes have evolved to achieve catalysis is unknown. The light-activated enzyme protochlorophyllide oxidoreductase (POR) catalyzes sequential hydride and proton transfers in the photoexcited and ground states, respectively, and is an excellent system for relating the effects of motions to catalysis. Here, we have used the temperature dependence of isotope effects and solvent viscosity measurements to analyze the dynamics coupled to the hydride and proton transfer steps in three cyanobacterial PORs and a related plant enzyme. We have related the dynamic profiles of each enzyme to their evolutionary origin. Motions coupled to light-driven hydride transfer are conserved across all POR enzymes, but those linked to thermally activated proton transfer are variable. Cyanobacterial PORs require complex and solvent-coupled dynamic networks to optimize the proton donor-acceptor distance, but evolutionary pressures appear to have minimized such networks in plant PORs. POR from Gloeobacter violaceus has features of both the cyanobacterial and plant enzymes, suggesting that the dynamic properties have been optimized during the evolution of POR. We infer that the differing trajectories in optimizing a catalytic structure are related to the stringency of the chemistry catalyzed and define a functional adaptation in which active site chemistry is protected from the dynamic effects of distal mutations that might otherwise impact negatively on enzyme catalysis.     

The role of protein surface charge in catalytic activity and chloroplast membrane association of the pea NADPH: protochlorophyllide oxidoreductase (POR) as revealed by alanine scanning mutagenesis

NADPH:protochlorophyllide oxidoreductase (POR) catalyzes the light-dependent reduction of protochlorophyllide (pchlide) to chlorophyllide (chlide) in the biosynthesis of chlorophyll. POR is a peripheral membrane protein that accumulates to high levels in the prolamellar bodies of vascular plant etioplasts and is present at low levels in the thylakoid membranes of developing and mature plastids. Clustered charged-to-alanine scanning mutagenesis of the pea (Pisum sativum L.) POR was carried out and the resulting mutant enzymes analyzed for their ability to catalyze pchlide photoconversion in vivo and to associate properly with thylakoid membrane preparations in vitro. Of 37 mutant enzymes examined, 5 retained wild-type levels of activity, 14 were catalytically inactive, and the remaining 18 exhibited altered levels of function. Several of the mutant enzymes showed temperature- dependent enzymatic activity, being inactive at 32°C, but partially active at 24°C. Mutations in predicted - helical regions of the protein showed the least effect on enzyme activity, whereas mutations in predicted -sheet regions of the protein showed a consistent adverse affect on enzyme function. In the absence of added NADPH, neither wild-type POR nor any of the mutant PORs resisted proteolysis by thermolysin following assembly onto the thylakoid membranes. In contrast, when NADPH was present in the assay mixture, 13 of the 37 mutant PORs examined were found to be resistant to thermolysin upon treatment, suggesting that the mutations did not affect their ability to be properly attached to the thylakoid membrane. In general, the replacement of charged amino acids by alanine in the most N- and C-terminal regions of the mature protein did not significantly affect POR assembly, whereas mutations within the central core of the protein (between residues 86 and 342) were incapable of proper attachment to the thylakoid. Failure to properly associate with the thylakoid membrane in a protease resistant manner was only weakly correlated to loss of catalytic function. These studies are a first step towards defining structural determinants crucial to POR function and intraorganellar localization.     

Secondary metabolite from Nostoc XPORK14A inhibits photosynthesis and growth of Synechocystis PCC 6803

Screening of 55 different cyanobacterial strains revealed that an extract from Nostoc XPORK14A drastically modifies the amplitude and kinetics of chlorophyll a fluorescence induction of Synechocystis PCC 6803 cells. After 2 d exposure to the Nostoc XPORK14A extract, Synechocystis PCC 6803 cells displayed reduced net photosynthetic activity and significantly modified electron transport properties of photosystem II under both light and dark conditions. However, the maximum oxidizable amount of P700 was not strongly affected. The extract also induced strong oxidative stress in Synechocystis PCC 6803 cells in both light and darkness. We identified the secondary metabolite of Nostoc XPORK14A causing these pronounced effects on Synechocystis cells. Mass spectrometry and nuclear magnetic resonance analyses revealed that this compound, designated as M22, has a non‐peptide structure. We propose that M22 possesses a dual‐action mechanism: firstly, by photogeneration of reactive oxygen species in the presence of light, which in turn affects the photosynthetic machinery of Synechocystis PCC 6803; and secondly, by altering the in vivo redox status of cells, possibly through inhibition of protein kinases.     

MACROMOLECULAR PHYSIOLOGY OF PLASTIDS : VIII. Pigment and Membrane Formation in Plastids of Barley Greening under Low Light Intensity

Sequential changes occurring in the etioplasts of the primary leaf of 7-day-old dark-grown barley seedlings upon continuous illumination with 20 lux have been investigated by electron microscopy, in vivo spectrophotometry, and thin-layer chromatography. Following photoconversion of the protochlorophyllide pigment to chlorophyllide and the structural transformation of the crystalline prolamellar bodies, the tubules of the prolamellar bodies are dispersed into the primary lamellar layers. As both chlorophyll a and b accumulate, extensive formation of grana takes place. After 4 hr of greening, protochlorophyllide starts to reaccumulate, and concomitantly both large and small crystalline prolamellar bodies are formed. This protochlorophyllide is rapidly photoconverted upon exposure of the leaves to high light intensity, which also effects a rapid reorganization of the recrystallized prolamellar bodies into primary lamellar layers.     

Discovery of the first light‐dependent protochlorophyllide oxidoreductase in anoxygenic phototrophic bacteria

In all photosynthetic organisms, chlorophylls function as light‐absorbing photopigments allowing the efficient harvesting of light energy. Chlorophyll biosynthesis recurs in similar ways in anoxygenic phototrophic proteobacteria as well as oxygenic phototrophic cyanobacteria and plants. Here, the biocatalytic conversion of protochlorophyllide to chlorophyllide is catalysed by evolutionary and structurally distinct protochlorophyllide reductases (PORs) in anoxygenic and oxygenic phototrophs. It is commonly assumed that anoxygenic phototrophs only contain oxygen‐sensitive dark‐operative PORs (DPORs), which catalyse protochlorophyllide reduction independent of the presence of light. In contrast, oxygenic phototrophs additionally (or exclusively) possess oxygen‐insensitive but light‐dependent PORs (LPORs). Based on this observation it was suggested that light‐dependent protochlorophyllide reduction first emerged as a consequence of increased atmospheric oxygen levels caused by oxygenic photosynthesis in cyanobacteria. Here, we provide experimental evidence for the presence of an LPOR in the anoxygenic phototrophic α‐proteobacterium Dinoroseobacter shibae DFL12^T. In vitro and in vivo functional assays unequivocally prove light‐dependent protochlorophyllide reduction by this enzyme and reveal that LPORs are not restricted to cyanobacteria and plants. Sequence‐based phylogenetic analyses reconcile our findings with current hypotheses about the evolution of LPORs by suggesting that the light‐dependent enzyme of D. shibae DFL12^T might have been obtained from cyanobacteria by horizontal gene transfer.     

More than just a pair of blue genes: how cyanobacteria adapt to changes in their light environment

Cyanobacteria require light to perform photosynthesis, but not all colors of light are equally useable for them. In particular, blue light-grown cyanobacterial strains, including the well-studied model organism Synechocystis sp. PCC 6803 (Synechocystis), have been observed to exhibit slower growth rates than white or red light-grown cells. In this issue of Physiologia Plantarum, Luimstra et al. (2020) have attempted to understand why cyanobacterial cells suffer under blue light. They measured the molecular and genetic responses of Synechocystis cells to being shifted from white light to blue light. They found that blue light-grown cells make changes that lead to a redistribution of energy flow between the two photosystems that power photosynthesis. These findings could help researchers identify avenues for optimizing photosynthesis in cyanobacterial species, a group of organisms which show great promise as potential solar-powered factories for the production of biofuels and other high-value products.     

Far-red light blocks greening of Arabidopsis seedlings via a phytochrome A-mediated change in plastid development.

We have characterized a far-red-light response that induces a novel pathway for plastid development in Arabidopsis seedlings. This response results in the inability of cotyledons to green upon subsequent white light illumination, and the response is suppressed by exogenous sucrose. Studies with mutants showed that this far-red block of greening is phytochrome A dependent and requires an intact downstream signaling pathway in which FHY1 and FHY3 may be components but in which HY5 is not. This highlights a previously undefined branchpoint in the phytochrome signaling pathway. Ultrastructural analysis showed that the far-red block correlates with both the failure of plastids to accumulate prolamellar bodies and the formation of vesicles in the stroma. We present evidence that the far-red block of greening is the result of severe repression of protochlorophyllide reductase (POR) genes by far-red light coupled with irreversible plastid damage. This results in the temporal separation of phytochrome-mediated POR; repression from light-dependent protochlorophyllide reduction, two processes that normally occur in coordination in white light.     

Photoactive Protochlorophyllide-Enzyme Complexes Reconstituted with PORA,PORB and PORC Proteins of A. thaliana: Fluorescence and Catalytic Properties

Photoactive Pchlide-POR-NADPH complexes were reconstituted using protochlorophyllide (Pchlide) and recombinant light-dependent protochlorophyllide oxidoreductase (POR) proteins, His₆-PORA, His₆-PORB and His₆-PORC, from Arabidopsis thaliana. We did not observe any differences in the kinetics of the protochlorophyllide photoreduction at room temperature among the PORA, PORB and PORC proteins. In contrast, the PORC protein showed lower yield of Chlide formation than PORA and PORB when preincubated in the dark for 30 min and then illuminated for a short time. The most significant observation was that reconstituted Pchlide-POR-NADPH complexes showed fluorescence maxima at 77 K similar to those observed for highly aggregated Pchlide-POR-NADPH complexes in prolamellar bodies (PLBs) in vivo. Homology models of PORA, PORB and PORC of Arabidopsis thaliana were developed to compare predicted structures of POR isoforms. There were only slight structural differences, mainly in the organisation of helices and loops, but not in the shape of whole molecules. This is the first comparative analysis of all POR isoforms functioning at different stages of A. thaliana development.     

Functional analysis of isoforms of NADPH: protochlorophyllide oxidoreductase (POR), PORB and PORC, in Arabidopsis thaliana

NADPH:protochlorophyllide oxidoreductase (POR) catalyzes the light-dependent reduction of protochlorophyllide. To elucidate the physiological function of three differentially regulated POR isoforms (PORA, PORB and PORC) in Arabidopsis thaliana, we isolated T-DNA tagged null mutants of porB and porC. The mature seedlings of the mutants had normal photosynthetic competencies, showing that PORB and PORC are interchangeable and functionally redundant in developed plants. In etiolated seedlings, only porB showed a reduction in the photoactive protochlorophyllide and the size of prolamellar bodies (PLBs), indicating that PORB, as well as PORA, functioned in PLB assembly and photoactive protochlorophyllide formation in etiolated seedlings. When illuminated, the etiolated porB seedling was able to green to a similar extent as the wild type, whereas the greening was significantly reduced under low light conditions. During greening, high light irradiation increased the level of PORC protein, and the greening of porC was repressed under high light conditions. The porB, but not porC, etiolated seedling was more sensitive to the far-red block of greening than the wild type, which is caused by depletion of endogenous POR proteins resulting in photo-oxidative damage. These results suggest that, at the onset of greening, PLBs are important for efficient capture of light energy for photoconversion under various light conditions, and PORC, which is induced by high light irradiation, contributes to photoprotection during greening of the etiolated seedlings.     

Isolation and characterization of photoactive complexes of NADPH:protochlorophyllide oxidoreductase from wheat

A photoactive substrate-enzyme complex of the NADPH:protochlorophyllide oxidoreductase (POR; EC 1. 3. 1. 33) was purified from etiolated Triticum aestivum L. by gel chromatography after solubilization of prolamellar bodies by dodecyl-maltoside. Irradiation by a 1-ms flash induced the phototransformation of protocholorophyllide a (Pchlide) with −196 °C absorbance and emission maxima at 640 and 643 nm, respectively. The apparent molecular weight of this complex was 112 ± 24 kDa, which indicates aggregation of enzyme subunits. By lowering the detergent concentration in the elution buffer, a 1080 ± 250-kDa particle was obtained which displayed the spectral properties of the predominant form of photoactive Pchlide in vivo (−196 °C absorbance and fluorescence maxima at 650 and 653 nm). In this complex, POR was the dominant polypeptide. Gel chromatography in the same conditions of an irradiated sample of solubilized prolamellar bodies indicated rapid disaggregation of the complex after Pchlide phototransformation. High performance liquid chromatographic analysis of the POR complexes obtained using two detergent concentrations indicates a possible association of zeaxanthin and violaxanthin with the photoactive complex. Received: 25 February 1998 / Accepted: 8 June 1998     

Novel Insights into the Enzymology,Regulation and Physiological Functions of Light-dependent Protochlorophyllide Oxidoreductase in Angiosperms

The reduction of protochlorophyllide (Pchlide) is a key regulatory step in the biosynthesis of chlorophyll in phototrophic organisms. Two distinct enzymes catalyze this reduction; a light-dependent NADPH:protochlorophyllide oxidoreductase (POR) and light-independent Pchlide reductase (DPOR). Both enzymes are widely distributed among phototrophic organisms with the exception that only POR is found in angiosperms and only DPOR in anoxygenic photosynthetic bacteria. Consequently, angiosperms become etiolated in the absence of light, since the reduction of Pchlide in angiosperms is solely dependent on POR. In eukaryotic phototrophs, POR is a nuclear-encoded single polypeptide and post-translationally imported into plastids. POR possesses unique features, its light-dependent catalytic activity, accumulation in plastids of dark-grown angiosperms (etioplasts) via binding to its substrate, Pchlide, and cofactor, NADPH, resulting in the formation of prolamellar bodies (PLBs), and rapid degradation after catalysis under subsequent illumination. During the last decade, considerable progress has been made in the study of the gene organization, catalytic mechanism, membrane association, regulation of the gene expression, and physiological function of POR. In this review, we provide a brief overview of DPOR and then summarize the current state of knowledge on the biochemistry and molecular biology of POR mainly in angiosperms. The physiological and evolutional implications of POR are also discussed.     

Properties of reformed prolamellar bodies from illuminated and redarkened etiolated wheat plants

Prolamellar bodies were isolated from etiolated leaves of wheat ( Triticum aestivum L. cv. Walde, Weibull), which were illuminated for 4 h and then grown in darkness for 16 h. The inner etiochloroplast membranes were isolated by differential centrifugation, and prolamellar bodies and thylakoids were separated on a 10–50% continuous sucrose density gradient. The reformed prolamellar bodies contained phototransformable protochlorophyllide as the main pigment as shown by low temperature fluorescence spectra and high performance liquid chromatography. After illumination with 3 flashes of white light almost all of the protochlorophyllide was transformed to chlorophyllide. In the thylakoids, however, most of the protochlorophyllide was not phototransformed. The reformed prolamellar bodies and the thylakoids showed a fluorescence emission ratio 657/633 nm of 5.6 and 0.5, respectively. Both membrane systems contained also chlorophyllide and chlorophyll synthesized during the illumination. Polyacrylamide gel electrophoresis showed the main chlorophyllide oxidoreductasse.
Teransmission and scanning electron micrographs indicated that the reformed prolamellar bodies are mainly of the "narrow" type and that the prolamellar body fraction had only a minor contamination with thylakoid membranes.
The results obtained showed that reformed prolamellar bodies isolated from illuminated redarkened etiolated wheat leaves had features very similar to the prolamellar bodies isolated from etiolated leaves. This provides support for the idea that prolamellar bodies are an important natural membrane system which plays a dynamic role in the development of the etio-chloroplasts in light.     

The NADPH-protochlorophyllide oxidoreductase is the major protein constituent of prolamellar bodies in wheat (Triticum aestivum L.)

A fraction of highly purified prolamellar bodies was isolated from etioplasts of wheat (Triticum aestivum L. cv. Starke II, Weibull), as previously described by Ryberg and Sundqvist (1982, Physiol. Plant., 56, 125–132). Studies on the protein composition revealed that only one major polypeptide of an apparent molecular weight of 36000 is present in the fraction of prolamellar bodies. This polypeptide was identified as the NADPH-protochlorophyllide oxidoreductase. The highest specific activity of the enzyme in etiolated leaf tissue was confirmed to be in the fraction of prolamellar bodies.Abbreviations PChlide protochlorophyllide - PLB prolamellar body - PT prothylakoid     

Arabidopsis light-dependent protochlorophyllide oxidoreductase A (PORA) is essential for normal plant growth and development

During skotomorphogenesis in angiosperms, NADPH:protochlorophyllide oxidoreductase (POR) forms an aggregate of photolabile NADPH-POR-protochlorophyllide (Pchlide) ternary complexes localized to the prolamellar bodies within etioplasts. During photomorphogenesis, POR catalyzes the light-dependent reduction of Pchlide a to chlorophyllide (Chlide) a, which is subsequently converted to chlorophyll (Chl). In Arabidopsis there are three structurally related POR genes, denoted PORA, PORB and PORC. The PORA and PORB proteins accumulate during skotomorphogenesis. During illumination, PORA is only transiently expressed, whereas PORB and PORC persist and are responsible for bulk Chl synthesis throughout plant development. Here we have tested whether PORA is important for skotomorphogenesis by assisting in etioplast development, and normal photomorphogenic development. Using reverse genetic approaches, we have identified the porA-1 null mutant, which contains an insertion of the maize Dissociation transposable element in the PORA gene. Additionally, we have characterized PORA RNAi lines. The porA-1 and PORA RNAi lines display severe photoautotrophic growth defects, which can be partially rescued on sucrose-supplemented growth media. Elimination of PORA during skotomorphogenesis results in reductions in the volume and frequency of prolamellar bodies, and in photoactive Pchlide conversion. The porA-1 mutant characterization thus establishes a quantitative requirement for PORA in etioplast development by demonstrating significant membrane ultrastructural and biochemical defects, in addition to suggesting PORA-specific functions in photomorphogenesis and plant development.     

CHANGES INDUCED BY LOW LIGHT INTENSITIES ON THE PROLAMELLAR BODY OF 8-DAY,DARK-GROWN SEEDLINGS

Etioplasts of 8-day-old, dark-grown seedlings of Phaseolus vulgaris contain large, crystalline prolamellar bodies. The basic structural unit within the prolamellar body is a six-pointed star (star module) with four tubules fusing at each of the nodes. With sufficient illumination some of the tubules are withdrawn and the crystalline prolamellar body transforms to a complex tangle of tubules, the reacted prolamellar body. In vivo spectrophotometry and electron microscopic observations were carried out on portions of the same leaves after varying periods of illumination with low light intensity. Protochlorophyllide transformation was normal. However, the structural changes are not closely tied to protochlorophyllide conversion. The pigment conversion is complete after 20 sec of illumination, but 80% of the prolamellar bodies are still in the crystalline form after 20 min of illumination. After 1 and 2 hr of illumination all prolamellar bodies are reacted. After 4 hr of continuous illumination 35%, and by 12 hr 60%, of the prolamellar bodies returned to the crystalline form. Spectrophotometric evidence and presence of grana show chlorophyll synthesis during this period. The coexistence of grana and the crystalline prolamellar body indicates that when insufficient photosynthetic membrane constituents are provided by the photo-reactions, under low light intensity, the membranes of the reacted prolamellar body will be forced to reform a crystalline prolamellar body.     

光下叶绿素缺乏的大麦突变体NYB中叶绿素合成再探

研究一种原叶绿素酯还原酶（POR）的大麦突变体Ⅳ阳光下合成叶绿素的结果表明,NYB中PORB的含量比野生型低。NYB前质体中原片层体的大小和数量与野生型差不多,但其结构比野生型的松散。暗中生长的突变体内POR蛋白复合物LHPP比野生型少。不同光照强度下叶绿素积累的结果显示,光照度越强,突变体与野生型的叶绿素差异越显著。由于porB是单拷贝的,所以推测突变体中部分porB mRNA可能产生错误的剪切拼接,以致光下突变体Ⅳ阳仍然能合成叶绿素。