Protochlorophyllide Reduction: a Key Step in the Greening of Plants

The reduction of Protochlorophyllide (Pchlide) is a major regulatorystep in the biosynthesis of chlorophyll (Chl) in oxygenic phototrophs.Two different enzymes catalyze this reduction: a light-dependentenzyme (LPOR), which is unique as a consequence of its directutilization of light for catalysis; and a light-independentPchlide reductase (DPOR). Since the reduction of Pchlide inangiosperms is catalyzed exclusively by LPOR, they become etiolatedin the absence of light. LPOR, a major protein in etioplastmembranes, consists of a single polypeptide and it exists asa ternary complex with its substrates, Pchlide and NADPH. Bycontrast to the copious information about LPOR, limited informationabout DPOR has been reported. Recent molecular genetic analysesin a cyanobacterium and a green alga have revealed that at leastthe three genes, namely, chlL, chlN and chlB, encode proteinsessential for the activity of DPOR. These genes are widely distributedamong phototrophic organisms with the exception of angiospermsand Euglenophyta. This distribution seems to be well correlatedwith light-independent greening ability. These genes might havebeen lost during the evolution of gymnosperms to angiosperms.The similarities among the deduced amino acid sequences of thethree gene products and the subunits of nitrogenase suggestan evolutionary relationship between DPOR and nitrogenase. Theidentification of genes for the reduction of Pchlide providesthe groundwork for investigations of the mechanism that regulatesthe synthesis of Chl, which is closely coordinated with greeningin plants. ¹Recipient of the Plant and Cell Physiology Award for the Paperof Excellence (PCP Award), 1995.     

Cloning of the Gene Encoding a Protochlorophyllide Reductase: the Physiological Significance of the Co-Existence of Light-Dependent and -Independent Protochlorophyllide Reduction Systems in the Cyanobacterium Plectonema boryanum

Cyanobacteria have two protochlorophyllide (Pchlide) reductasescatalyzing the conversion of Pchlide to chloro-phyllide, a keystep in the biosynthetic pathway of chlorophylls (Chls); a light-dependent(LPOR) and a light-independent (DPOR) reductase. We found anopen reading frame (ORF322) in a 2,131-bp EcoRI fragment fromthe genomic DNA of the cyanobacterium Plectonema boryanum. Becausethe deduced amino acid sequence showed a high similarity tothose of various plant LPORs and the LPOR activity was detectedin the soluble fraction of Esche-richia coli cells over-expressingthe ORF322 protein, ORF322 was defined as the por gene encodingLPOR in P. boryanum. A por-disrupted mutant, YFP12, was isolatedby targeted mutagenesiss to investigate the physiological importanceof LPOR. YFP12 grew as well as wild type under low light conditions(10-25 µE m^–2 S^–1). However, its growth wassignificantly retarded as a result of a significant decreasein its Chl content under higher light conditions (85-130 µEm^–2 s^–1). Furthermore, YFP12 stopped growing andsuffered from photobleaching under the highest light intensity(170 µE m^–2 s^–1). In contrast, a chlL-dis-rupted(DPOR-less) mutant YFC2 grew as well as wild type irrespectiveof light intensity. From these phenotypic characteristics, weconcluded that, although both LPOR and DPOR contribute to Chlsynthesis in the cells growing in the light, the extent of thecontribution by LPOR increases with increasing light intensity;without it, the cells are unable to grow under light intensitiesof more than 130 µ Em^–2s-^–. (Received September 26, 1997; Accepted November 21, 1997)     

A short overview of chlorophyll biosynthesis in algae

Chlorophylls are the most abundant classes of natural pigments and their biosynthesis is therefore a major metabolic activity in the ecosphere. Two pathways exist for chlorophyll biosynthesis, one taking place in darkness and the other requiring continuous light as a precondition. The key process for Chl synthesis is the reduction of protochlorophyllide (Pchlide). This enzymatic reaction is catalysed by two different enzymes — DPOR (dark-operative Pchlide oxidoreductase) or the structurally distinct LPOR (light-dependent Pchlide oxidoreductase). DPOR which consists of three subunits encoded by three plastid genes in eukaryotes was subject of our study. A short overview of our present knowledge of chlorophyll biosynthesis in Chlamydomonas reinhardtii in comparison with other plants is presented. Presented at the International Symposium Biology and Taxonomy of Green Algae V, Smolenice, June 26–29, 2007, Slovakia.     

The influence of growth conditions on the synthesis of molybdenum cofactor in Proteus mirabilis

Cell-free extracts of Proteus mirabilis were able to reconstitute NADPH-dependent assimilatory nitrate reductase in crude extracts of the Neurospora crassa mutant strain nit-1, lacking molybdenum cofactor. Molybdenum cofactor was formed in the cytoplasm of the bacterium even in the presence of oxygen during growth though under these conditions no molybdo enzymes are formed. As a consequence no cofactor could be released by acid treatment from membranes of cells grown aerobically. The amount of cofactor released from membranes of cells grown anaerobically under various conditions was proportional to the amount of molybdo enzymes formed. During growth in the presence of tungstate a cofactor, which lacks molybdenum, was found in the cytoplasm. For detection of this so-called demolybdo cofactor the presence of molybdate during reconstitution was essential. Moreover, the cytoplasmic cofactor pool in cells grown in the presence of tungstate appeared to be two to three times higher than in cells grown under similar conditions without tungstate. After anaerobic growth in the presence of tungstate, the inactive demolybdo reductases were shown to contain partly no cofactor and partly a demolybdo cofactor. The P. mirabilis chlorate resistant mutant S 556 did not contain molybdenum cofactor. In two other chl-mutants the cofactor activity was the same as in the wild type.     

The correlation between the protein composition of cytoplasmic membranes and the formation of nitrate reductase A,chlorate reductase C and tetrathionate reductase in Proteus mirabilis wild type and some chlorate resistant mutants

Three genotypically different chlorate resistant mutants, chl I, chl II and chl III, appeared to lack completely nitrate reductase A, chlorate reductase C and tetrathionate reductase activity. Fumarate reductase is only partially affected in chl I and chl III and unaffected in chl II. Formate dehydrogenase is only partially diminished in chl II, hydrogenase is diminished in chl I and chl II and completely absent in chl III.Subunits of nitrate reductase A, chlorate reductase C and tetrathionate reductase have been identified in protein profiles of purified cytoplasmic membranes from the wild type and the three mutant strains, grown under various conditions. Only the presence and absence of the largest subunits of these enzymes appeared to be correlated with their repression and derepression in the wild type membranes. On the cytoplasmic membranes of the chl I and chl III mutants these subunits lack for the greater part. In the chl II mutant, however, these subunits are inserted in the membrane all together after anaerobic growth with or without nitrate.A model for the repression/derepression mechanism for the reductases has been proposed. It includes repression by cytochrome b components, whereas the redox-state of the nitrate reductase A molecule itself is also involved in its derepression under anaerobic conditions.     

Origin and evolution of the light-dependent protochlorophyllide oxidoreductase (LPOR) genes

Abstract: Light‐dependent NADPH‐protochlorophyllide oxidoreductase (LPOR) is a nuclear‐encoded chloroplast protein in green algae and higher plants which catalyzes the light‐dependent reduction of protochlorophyllide to chlorophyllide. Light‐dependent chlorophyll biosynthesis occurs in all oxygenic photosynthetic organisms. With the exception of angiosperms, this pathway coexists with a separate light‐independent chlorophyll biosynthetic pathway, which is catalyzed by light‐independent protochlorophyllide reductase (DPOR) in the dark. In contrast, the light‐dependent function of chlorophyll biosynthesis is absent from anoxygenic photosynthetic bacteria. Consequently, the question is whether cyanobacteria are the ancestors of all organisms that conduct light‐dependent chlorophyll biosynthesis. If so, how did photosynthetic eukaryotes acquire the homologous genes of LPOR in their nuclear genomes? The large number of complete genome sequences now available allow us to detect the evolutionary history of LPOR genes by conducting a genome‐wide sequence comparison and phylogenetic analysis. Here, we show the results of a detailed phylogenetic analysis of LPOR and other functionally related enzymes in the short chain dehydrogenase/reductase (SDR) family. We propose that the LPOR gene originated in the cyanobacterial genome before the divergence of eukaryotic photosynthetic organisms. We postulated that the photosynthetic eukaryotes obtained their LPOR homologues through endosymbiotic gene transfer.     

Inhibition of chlorophyll biosynthesis at the protochlorophyllide reduction step results in the parallel depletion of Photosystem I and Photosystem II in the cyanobacterium Synechocystis PCC 6803

In most oxygenic phototrophs, including cyanobacteria, two independent enzymes catalyze the reduction of protochlorophyllide to chlorophyllide, which is the penultimate step in chlorophyll (Chl) biosynthesis. One is light-dependent NADPH:protochlorophyllide oxidoreductase (LPOR) and the second type is dark-operative protochlorophyllide oxidoreductase (DPOR). To clarify the roles of both enzymes, we assessed synthesis and accumulation of Chl-binding proteins in mutants of cyanobacterium Synechocystis PCC 6803 that either completely lack LPOR or possess low levels of the active enzyme due to its ectopic regulatable expression. The LPOR-less mutant grew photoautotrophically in moderate light and contained a maximum of 20 % of the wild-type (WT) Chl level. Both Photosystem II (PSII) and Photosystem I (PSI) were reduced to the same degree. Accumulation of PSII was mostly limited by the synthesis of antennae CP43 and especially CP47 as indicated by the accumulation of reaction center assembly complexes. The phenotype of the LPOR-less mutant was comparable to the strain lacking DPOR that also contained <25 % of the wild-type level of PSII and PSI when cultivated under light-activated heterotrophic growth conditions. However, in the latter case, we detected no reaction center assembly complexes, indicating that synthesis was almost completely inhibited for all Chl-proteins, including the D1 and D2 proteins.     

Substrate recognition of nitrogenase-like dark operative protochlorophyllide oxidoreductase from Prochlorococcus marinus

Chlorophyll and bacteriochlorophyll biosynthesis requires the two-electron reduction of protochlorophyllide a ringDbya protochlorophyllide oxidoreductase to form chlorophyllide a. A light-dependent (light-dependent Pchlide oxidoreductase (LPOR)) and an unrelated dark operative enzyme (dark operative Pchlide oxidoreductase (DPOR)) are known. DPOR plays an important role in chlorophyll biosynthesis of gymnosperms, mosses, ferns, algae, and photosynthetic bacteria in the absence of light. Although DPOR shares significant amino acid sequence homologies with nitrogenase, only the initial catalytic steps resemble nitrogenase catalysis. Substrate coordination and subsequent [Fe-S] cluster-dependent catalysis were proposed to be unrelated. Here we characterized the first cyanobacterial DPOR consisting of the homodimeric protein complex ChlL(2) and a heterotetrameric protein complex (ChlNB)(2). The ChlL(2) dimer contains one EPR active [4Fe-4S] cluster, whereas the (ChlNB)(2) complex exhibited EPR signals for two [4Fe-4S] clusters with differences in their g values and temperature-dependent relaxation behavior. These findings indicate variations in the geometry of the individual [4Fe-4S] clusters found in (ChlNB)(2). For the analysis of DPOR substrate recognition, 11 synthetic derivatives with altered substituents on the four pyrrole rings and the isocyclic ring plus eight chlorophyll biosynthetic intermediates were tested as DPOR substrates. Although DPOR tolerated minor modifications of the ring substituents on rings A-C, the catalytic target ring D was apparently found to be coordinated with high specificity. Furthermore, protochlorophyllide a, the corresponding [8-vinyl]-derivative and protochlorophyllide b were equally utilized as substrates. Distinct differences from substrate binding by LPOR were observed. Alternative biosynthetic routes for cyanobacterial chlorophyll biosynthesis with regard to the reduction of the C8-vinyl group and the interconversion of a chlorophyll a/b type C7 methyl/formyl group were deduced.     

Regulation of the ribonucleotide reductases in Lactococcus lactis subsp. cremoris

Lactococcus lactis has two essential ribonucleotide reductases for DNA biosynthesis and repair which are affected in the presence or absence of oxygen. Expression of glutaredoxin like protein (NrdH), the hydrogen donor for ribonucleotide reductase, was found to be regulated by the FNR like proteins (FlpA and FlpB). Proteomics study demonstrated that expression level of NrdH significantly decreased in the flpA and flpAB deletion mutants. The nrdH gene is located in an nrdHIEF operon and encoding the NrdEF ribonucleotide reductase, which is active under aerobic and anaerobic conditions. Regulation of expression of the nrdHIEF operons was investigated using beta-galactosidase as a reporter gene. The 588 bp fragment containing the nrdH promoter and gene cloned into the pORI vector immediately upstream of a promoterless lacZ gene. Constructed plasmid was transferred into wild type (MG1363), single mutant (flpA orflpB) and double mutant (flpAB). Aerobically, nrdH promoter activity is 15-fold higher than anaerobic expression.     

Rubredoxin:oxygen oxidoreductase enhances survival of Desulfovibrio vulgaris hildenborough under microaerophilic conditions

Genes for superoxide reductase (Sor), rubredoxin (Rub), and rubredoxin:oxygen oxidoreductase (Roo) are located in close proximity in the chromosome of Desulfovibrio vulgaris Hildenborough. Protein blots confirmed the absence of Roo from roo mutant and sor-rub-roo (srr) mutant cells and its presence in sor mutant and wild-type cells grown under anaerobic conditions. Oxygen reduction rates of the roo and srr mutants were 20 to 40% lower than those of the wild type and the sor mutant, indicating that Roo functions as an O2 reductase in vivo. Survival of single cells incubated for 5 days on agar plates under microaerophilic conditions (1% air) was 85% for the sor, 4% for the roo, and 0.7% for the srr mutant relative to that of the wild type (100%). The similar survival rates of sor mutant and wild-type cells suggest that O2 reduction by Roo prevents the formation of reactive oxygen species (ROS) under these conditions; i.e., the ROS-reducing enzyme Sor is only needed for survival when Roo is missing. In contrast, the sor mutant was inactivated much more rapidly than the roo mutant when liquid cultures were incubated in 100% air, indicating that O2 reduction by Roo and other terminal oxidases did not prevent ROS formation under these conditions. Competition of Sor and Roo for limited reduced Rub was suggested by the observation that the roo mutant survived better than the wild type under fully aerobic conditions. The roo mutant was more strongly inhibited than the wild type by the nitric oxide (NO)-generating compound S-nitrosoglutathione, indicating that Roo may also serve as an NO reductase in vivo.     

Regulation of reductase formation in Proteus mirabilis

Summary The levels of several redox enzymes in a chlorate-resistant mutant of Proteus mirabilis, which is partially affected in the formation of formate hydrogenlyase, thiosulfate reductase and tetrathionate reductase, were compared with those of the wild type. The composition of the electron transport system of both strains was almost the same in cells grown aerobically, but very different in cells grown anaerobically. In the mutant, the cytochrome content increased twofold, whereas the level of the anaerobic enzymes is strongly diminished. The anaerobic formation of electron transport components in the mutant was, in contrast to that of the wild type, not influenced significantly by azide. During anaerobic growth with nitrate low levels of a functional nitrate reductase system were formed in the mutant. Under these conditions the formation of formate dehydrogenase, formate hydrogenlyase, formate oxidase, thiosulfate reductase, tetrathionate reductase, cytochrome b_563,5 and partly that of cytochrome a₂, was repressed. The repressive effect of nitrate, however, was completely abolished by azide. Therefore, it seems likely that a functional nitrate reductase system, rather than nitrate, controls the formation of the enzymes repressible by nitrate.     

Properties of nitrate reductase from Fusarium oxysporum 11dn1 fungi grown under aerobic and anaerobic conditions

Production of nitrate reductase was studied in 15 species of microscopic fungi grown on a nitrate-containing medium. Experiments were performed with Fusarium oxysporum 11dn1, a fungus capable of producing nitrous oxide as the end product of denitrification. Moreover, a shift from aerobic to anaerobic conditions of growth was accompanied by a sharp increase in the activity of nitrate reductase. Studies of nitrate reductase from the mycelium of Fusarium oxysporum 11dn1, grown under aerobic and anaerobic conditions, showed that this enzyme belongs to molybdenum-containing nitrate reductases. The enzymes under study differed in the molecular weight, temperature optimum, and other properties. Nitrate reductase from the mycelium grown under aerobic conditions was shown to belong to the class of assimilatory enzymes. However, nitrate reductase from the mycelium grown anaerobically had a dissimilatory function. An increase in the activity of dissimilatory nitrate reductase, observed under anaerobic conditions, was associated with de novo synthesis of the enzyme.     

Nicotinamide is a specific inhibitor of dark-operative protochlorophyllide oxidoreductase,a nitrogenase-like enzyme,from Rhodobacter capsulatus

Dark-operative protochlorophyllide oxidoreductase (DPOR) is a nitrogenase-like enzyme consisting of two components, L-protein as a reductase component and NB-protein as a catalytic component. Elucidation of the crystal structures of NB-protein (Muraki et al., Nature 2010, 465: 110–114) has enabled us to study its reaction mechanism in combination with biochemical analysis. Here we demonstrate that nicotinamide (NA) inhibits DPOR activity by blocking the electron transfer from L-protein to NB-protein. A reaction scheme of DPOR, in which the binding of protochlorophyllide (Pchlide) to the NB-protein precedes the electron transfer from the L-protein, is proposed based on the NA effects.     

Evidence for a Second Nitrate Reductase Activity That Is Distinct from the Respiratory Enzyme in Salmonella typhimurium

Significant nitrate reductase activity was detected in mutants of Salmonella typhimurium which mapped at or near chlC and which were incapable of growth with nitrate as electron acceptor. The same mutants were sensitive to chlorate and performed sufficient nitrate reduction to permit anaerobic growth with nitrate as the sole nitrogen source in media containing glucose. The mutant nitrate-reducing protein did not migrate with the wild-type nitrate reductase in polyacrylamide electrophoretic gels. Studies of the electrophoretic mobility in gels of different polyacrylamide concentration revealed that the wild-type and mutant nitrate reductases differed significantly in both size and charge. The second enzyme also differed from the wild-type major enzyme in its response to repression by low pH and its lack of response to repression by glucose. The same mutants were found to be derepressed for nitrite reductase and for a cytochrome with a maximal reduced absorbance at 555 nm at 25°C. This cytochrome was not detected in preparations of the wild type grown under the same conditions. Extracts of these mutants contained normal amounts of the b-type cytochromes which, in the wild type, were associated with nitrate reductase and formate dehydrogenase, respectively, although they could not mediate the oxidation of these cytochromes with nitrate. They were capable of oxidizing the derepressed 555-nm peak cytochrome with nitrate. It is suggested that these mutants synthesize a nitrate-reducing enzyme which is distinct from the chlC gene product and which is repressed in the wild type during anaerobic growth with nitrate.     

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.     

Fumarate reductase is a soluble enzyme in anaerobically grown Shewanella putrefaciens MR-1

Abstract The expression and distribution of fumarate reductase activity was examined in Shewanella putrefaciens MR-1. Fumarate reductase was expressed at very low levels in aerobically grown cell and was markedly induced by growth under anaerobic conditions. Cells were fractionated into soluble and purified membrane components by four different methods. For all four methods used, and in marked contrast to the membrane-bound fumarate reductases of other bacteria, ≧ 98% of the fumarate reductase activity was localized in the soluble fraction. In cells subjected to osmotic shock or treated with lysozyme and EDTA to form spheroplasts, the specific activity of fumarate reductase was highest in the periplasmic fraction, while the majority of total fumarate reductase activity was in the cytoplasmic fraction.     

Nitrate Reductase and Nitrous Oxide Production by Fusarium oxysporum 11dn1 Under Aerobic and Anaerobic Conditions

The fungus Fusarium oxysporum 11dn1 was found to be able to grow and produce nitrous oxide on nitrate-containing medium in anaerobic conditions. The rate of nitrous oxide formation was three to six orders of magnitude lower than the rates of molecular nitrogen production by common denitrifying bacteria. Acetylene and ammonia did not affect the release of nitrous oxide release. It was shown that under anaerobic conditions fast increase of nitrate reductase activity occurred, caused by the synthesis of enzyme de novo and protein dephosphorylation. Reverse transfer of the mycelium to aerobic conditions led to a decline in nitrate reductase activity and stopped nitrous oxide production. The presence of two nitrate reductases was shown, which differed in molecular mass, location, temperature optima, and activity in nitrate- and ammonium-containing media. Two enzymes represent assimilatory and dissimilatory nitrate reductases, which are active in aerobic and anaerobic conditions, respectively. Received: 2 February 2000 / Accepted: 28 February 2000     

Functional evaluation of a nitrogenase-like protochlorophyllide reductase encoded by the chloroplast DNA of Physcomitrella patens in the cyanobacterium Leptolyngbya boryana

Dark-operative protochlorophyllide (Pchlide) oxidoreductase (DPOR) is a nitrogenase-like enzyme consisting of the two components, L-protein (a ChlL dimer) and NB-protein (a ChlN-ChlB heterotetramer), to catalyze Pchlide reduction in Chl biosynthesis. While nitrogenase is distributed only among certain prokaryotes, the probable structural genes for DPOR are encoded by chloroplast DNA in lower plants. Here we show functional evaluation of DPOR encoded by chloroplast DNA in a moss Physcomitrella patens by the complementation analysis of the cyanobacterium Leptolyngbya boryana and the heterologous reconstitution of the moss L-protein and the cyanobacterial NB-protein. Two shuttle vectors to overexpress chlL and chlN-chlB from P. patens were introduced into the cyanobacterial chlL- and chlB-lacking mutants, respectively. Both transformants restored the ability to perform Chl biosynthesis in the dark, indicating that the chloroplast-encoded DPOR components form an active complex with the cyanobacterial components. The L-protein of P. patens was purified from the cyanobacterial transformant, and DPOR activity was reconstituted in a heterologous combination with the cyanobacterial NB-protein. The specific activity of the L-protein from P. patens was determined to be 118 nmol min(-1) mg (-1), which is even higher than that of the cyanobacterial L-protein (76 nmol min(-1) mg (-1)). Upon exposure to air, the activity of the L-protein from P. patens decayed with a half-life of 30 s, which was eight times faster than that of the cyanobacterial L-protein (240 s). These results suggested that the chloroplast-encoded L-protein functions as efficiently as the cyanobacterial L-protein but is more oxygen labile than the cyanobacterial L-protein.     

Nitrofurazone-reducing enzymes in E. coli and their role in drug activation in vivo.

Earlier work showed that Escherichia coli contains at least two enzymes which reduce nitrofurazone and other nitrofuran derivatives. One of these enzymes is lacking in some nitrofurazone-resistant mutant strains. We now report that there are three separable nitrofuran reductases in this organism: reductase I (mol. wt. approximately 50 000, insensitive to O2), reductase IIa (mol. wt. approximately 120 000, inhibited by oxygen), reductase IIb (mol. wt. approximately 700 000, inhibited by O2). Unstable metabolites formed during the reduction of nitrofurazone by preparations containing reductases IIa and IIb produce breaks in DNA in vitro. In vivo experiments with nitrofurazone-resistant strains, which lack reductase II but contain reductases IIa and IIb, demonstrated that lethality, mutation, and DNA breakage are all greatly increased when cultures are incubated under anaerobic conditions, i.e., conditions such that reductase II is active. These results provide further evidence for the importance of reductive activation of nitrofurazone.