Chloroplast biogenesis 84: solubilization and partial purification of membrane-bound [4-vinyl]chlorophyllide a reductase from etiolated barley leaves

[4-Vinyl] chlorophyllide a reductase (4VCR) is a key enzyme of the chlorophyll (Chl) biosynthetic pathway. It catalyzes the conversion of divinyl chlorophyllide (Chlide) a to monovinyl Chlide a by reduction of the vinyl group at position 4 of the macrocycle to ethyl. 4VCR is a membrane-bound enzyme, embedded in etioplast and etiochloroplast membranes. A study of the regulation and properties of this enzyme is mandatory for a comprehensive understanding of the biosynthetic heterogeneity of Chl biosynthesis. Solubilization and partial purification of 4VCR are described for the first time. The enzyme was solubilized with 5 mM Chaps and was partially purified by chromatography on DEAE-Sephacel and Cibacron Blue 3GA-1000 agarose. An overall 20-fold purification was achieved. The partially purified enzyme was stable for several months at -80 degrees C.     

Identification of a vinyl reductase gene for chlorophyll synthesis in Arabidopsis thaliana and implications for the evolution of Prochlorococcus species

Chlorophyll metabolism has been extensively studied with various organisms, and almost all of the chlorophyll biosynthetic genes have been identified in higher plants. However, only the gene for 3,8-divinyl protochlorophyllide a 8-vinyl reductase (DVR), which is indispensable for monovinyl chlorophyll synthesis, has not been identified yet. In this study, we isolated an Arabidopsis thaliana mutant that accumulated divinyl chlorophyll instead of monovinyl chlorophyll by ethyl methanesulfonate mutagenesis. Map-based cloning of this mutant resulted in the identification of a gene (AT5G18660) that shows sequence similarity with isoflavone reductase genes. The mutant phenotype was complemented by the transformation with the wild-type gene. A recombinant protein encoded by AT5G18660 was expressed in Escherichia coli and found to catalyze the conversion of divinyl chlorophyllide to monovinyl chlorophyllide, thereby demonstrating that the gene encodes a functional DVR. DVR is encoded by a single copy gene in the A. thaliana genome. With the identification of DVR, finally all genes required for chlorophyll biosynthesis have been identified in higher plants. Analysis of the complete genome of A. thaliana showed that it has 15 enzymes encoded by 27 genes for chlorophyll biosynthesis from glutamyl-tRNA(glu) to chlorophyll b. Furthermore, identification of the DVR gene helped understanding the evolution of Prochlorococcus marinus, a marine cyanobacterium that is dominant in the open ocean and is uncommon in using divinyl chlorophylls. A DVR homolog was not found in the genome of P. marinus but found in the Synechococcus sp WH8102 genome, which is consistent with the distribution of divinyl chlorophyll in marine cyanobacteria of the genera Prochlorococcus and Synechococcus.     

Chloroplast biogenesis. Demonstration of the monovinyl and divinyl monocarboxylic routes of chlorophyll biosynthesis in higher plants

It is shown that barley (Hordeum vulgare), a dark monovinyl/light divinyl plant species, and cucumber (Cucumis sativus L.) a dark divinyl/light divinyl plant species synthesize monovinyl and divinyl protochlorophyllide in darkness from monovinyl and divinyl protoporphyrin IX via two distinct monovinyl and divinyl monocarboxylic chlorophyll biosynthetic routes. Evidence for the operation of monovinyl monocarboxylic biosynthetic routes consisted (a) in demonstrating the conversion of delta-aminolevulinic acid to monovinyl protoporphyrin and to monovinyl Mg-protoporphyrins, and (b) in demonstrating the conversion of these tetrapyrroles to monovinyl protochlorophyllide by both isolated barley and cucumber etiochloroplasts. Likewise, evidence for the operation of divinyl monocarboxylic chlorophyll biosynthetic routes consisted (a) in demonstrating the biosynthesis of divinyl protoporphyrin and divinyl Mg-protoporphyrins from delta-aminolevulinic acid, and (b) in demonstrating the conversion of the latter tetrapyrroles to divinyl protochlorophyllide. Finally, it was shown that the divinyl tetrapyrrole substrates were metabolized differently by barley and cucumber. For example, divinyl protoporphyrin, divinyl Mg-protoporphyrin, and divinyl Mg-protoporphyrin monoester were converted predominantly to monovinyl protochlorophyllide and to smaller amounts of divinyl protochlorophyllide by barley etiochloroplasts. In contrast, cucumber etiochloroplasts converted the above substrates predominantly to divinyl protochlorophyllide, although smaller amounts of monovinyl protochlorophyllide were also formed. Furthermore, it was shown that monovinyl protochlorophyllide was not formed from divinyl protochlorophyllide either in barley or in cucumber etiochloroplasts. These metabolic differences are explained by the presence of strong biosynthetic interconnections between the divinyl and monovinyl monocarboxylic routes, prior to divinyl protochlorophyllide formation, in barley but not in cucumber.     

Chloroplast Biogenesis 60 : Conversion of Divinyl Protochlorophyllide to Monovinyl Protochlorophyllide in Green(ing) Barley, a Dark Monovinyl/Light Divinyl Plant Species

In higher plants, most of the chlorophyll a is formed via the divinyl and monovinyl chlorophyll monocarboxylic biosynthetic routes. These two routes are strongly interconnected prior to protochlorophyllide formation in barley (Hordeum vulgare L. cv Morex), a dark monovinyl-light divinyl plant species, but not in cucumber (Cucumis sativus L. cv Beit Alpha MR), a dark divinyl-light divinyl plant species (BC Tripathy, CA Rebeiz, 1986 J Biol Chem 261: 13556-13564). It is shown that in dark monovinyl-light divinyl plant species such as barley, the divinyl and monovinyl monocarboxylic routes become interconnected at the level of protochlorophyllide during transition from the divinyl to the monovinyl protochlorophyllide biosynthetic mode. In cucumber, a dark divinyl-light divinyl plant species, in which the monovinyl monocarboxylic biosynthetic route becomes preponderant only after an abnormally long sojourn in darkness, the conversion of divinyl to monovinyl protochlorophyllide does not take place on the barley time-scale of incubation.     

Separation of monovinyl and divinyl protochlorophyllides and chlorophyllides from etiolated and phototransformed cucumber cotyledons

A method was developed to separate the monovinyl and divinyl forms of protochlorophyllide and chlorophyllide by high pressure liquid chromatography using a silicic acid column coated with dodecyl residues and a moving phase containing the lipophilic cation, tetrabutyl ammonium. The solvent was 70% methyl alcohol containing varying amounts of methyl ethyl ketone. The separation was carried out at 0°C. This method was used to test and confirm a previous report that, in cucumber cotyledons, divinyl protochlorophyllide is phototransformed to give divinyl chlorophyllide, which is biologically unstable and disappears rapidly in the dark.     

Chloroplast biogenesis 76. Regulation of 4-vinyl reduction during conversion of divinyl Mg-protoporphyrin IX to monovinyl protochlorophyllide a is controlled by plastid membrane and stromal factors

Most of the chlorophyll (Chl) a of green plants is formed via two biosynthetic routes, namely the carboxylic divinyl and monovinyl chlorophyll biosynthetic routes. These two routes are linked by (4-vinyl) reductases that convert divinyl tetrapyrroles to monovinyl tetrapyrroles by reduction of the vinyl group at position four of the macrocycle to ethyl. The activities of these two routes are very sensitive to cell disruption. For example in barley leaves, cell disruption, a mandatory step during plastid isolation, results in partial inactivation of the carboxylic divinyl route. Investigations with subplastidic fractions revealed that the carboxylic divinyl and monovinyl biosynthetic routes were regulated by a delicate interaction that involved plastid membranes, stroma, and reduced pyridine nucleotides. While the monovinyl biosynthetic route was very active in isolated plastid membranes, activation of the divinyl biosynthetic route required the joint presence of plastid membranes and stroma. Contrary to expectation, activity of the carboxylic divinyl biosynthetic route was greatly enhanced by addition of NADPH to the lysing buffer used during plastid membranes and stroma preparation. NADPH in cooperation with the plastid stroma may play an important regulatory role during the biosynthesis of divinyl and monovinyl protochlorophyllide a.     

Chloroplast biogenesis 92: In situ screening for divinyl chlorophyll(ide) a reductase mutants by spectrofluorometry

Chlorophyll biosynthetic heterogeneity is rooted mainly in parallel divinyl (DV) and monovinyl (MV) biosynthetic routes interconnected by 4-vinyl reductases (4VRs) that convert DV tetrapyrroles to MV tetrapyrroles by conversion of the vinyl group at position 4 of the macrocycle to ethyl. What is not clear at this stage is whether the various 4VR activities are catalyzed by one enzyme of broad specificity or by a family of enzymes encoded by one gene or multiple genes with each enzyme having narrow specificity. Additional research is needed to identify the various regulatory components of 4-vinyl reduction. In this undertaking, Arabidopsis mutants that accumulate DV chlorophyllide a and/or DV chlorophyll [Chl(ide)] a are likely to provide an appropriate resource. Because the Arabidopsis genome has been completely sequenced, the best strategy for identifying 4VR and/or putative regulatory 4VR genes is to screen Arabidopsis Chl mutants for DV Chl(ide) a accumulation. In wild-type Arabidopsis, a DV plant species, only MV chlorophyllide (Chlide) a is detectable. However in Chl mutants lacking 4VR activity, DV Chl(ide) a may accumulate in addition to MV Chl(ide) a. In the current work, an in situ assay of DV Chl(ide) a accumulation, suitable for screening a large number of mutants lacking 4-vinyl Chlide a reductase activity with minimal experimental handling, is described. The assay involves homogenization of the tissues in Tris-HCl:glycerol buffer and the recording of Soret excitation spectra at 77K. DV Chlide a formation is detected by a Soret excitation shoulder at 459 nm over a wide range of DV Chlide a/MV Chl a ratios. The DV Chlide a shoulder became undetectable at DV Chlide a/MV Chl a ratios less than 0.049, that is, at a DV Chlide a content of less than 5%.     

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.     

Chloroplast biogenesis 76. Regulation of 4-vinyl reduction during conversion of divinyl Mg-protoporphyrin IX to monovinyl protochlorophyllide a is controlled by plastid membrane and stromal factors

Most of the chlorophyll (Chl) a of green plants is formed via two biosynthetic routes, namely the carboxylic divinyl and monovinyl chlorophyll biosynthetic routes. These two routes are linked by (4-vinyl) reductases that convert divinyl tetrapyrroles to monovinyl tetrapyrroles by reduction of the vinyl group at position four of the macrocycle to ethyl. The activities of these two routes are very sensitive to cell disruption. For example in barley leaves, cell disruption, a mandatory step during plastid isolation, results in partial inactivation of the carboxylic divinyl route. Investigations with subplastidic fractions revealed that the carboxylic divinyl and monovinyl biosynthetic routes were regulated by a delicate interaction that involved plastid membranes, stroma, and reduced pyridine nucleotides. While the monovinyl biosynthetic route was very active in isolated plastid membranes, activation of the divinyl biosynthetic route required the joint presence of plastid membranes and stroma. Contrary to expectation, activity of the carboxylic divinyl biosynthetic route was greatly enhanced by addition of NADPH to the lysing buffer used during plastid membranes and stroma preparation. NADPH in cooperation with the plastid stroma may play an important regulatory role during the biosynthesis of divinyl and monovinyl protochlorophyllide a. This revised version was published online in June 2006 with corrections to the Cover Date.     

The sites of photoconversion of protochlorophyllide to chlorophyllide in barley seedlings

The photoreduction of protochlorophyllide a to chlorophyllide a in intact 6-day-old seedlings of etiolated barley (Hordeum vulgare) exhibits a small initial phase, followed by an induction period of about 1 hour before a rapid phase of additional chlorophyll formation begins. Cycloheximide, an inhibitor of protein synthesis, has no effect on the initial phase of conversion of preformed protochlorophyllide, but it either abolishes or severely inhibits the subsequent phase of rapid chlorophyll synthesis within 45 minutes of its application to the seedlings. An analysis of the biphasic inhibition process suggests that the lifetime of the enzyme controlling protochlorophyllide synthesis (probably δ-amino-levulinic acid synthetase) is not longer than 10 minutes.     

Chlorophyll a and b biosynthesis in the dark in etiolated leaves infiltrated by exogenous chlorophyllide a]

Exogenous chlorophyllide a was introduced into etiolated rye leaves by the vacuum-infiltration technique. Appearance and accumulation of chlorophylls a and b within the leaves are observed during continued darkening, protochlorophyllide photoreduction being avoided. The pigments are identified by the solubility in petroleum ether, paper chromatograms, the fluorescence maxima, the peculiarities of exciting light 430 and 460 nm effects on fluorescence intensity, the specific interaction with hydrochloric hydroxylamine. The conclusion is made that before illumination etioplasts already contain enzyme systems and substrates which provide esterification of chlorophyllide a to chlorophyll a and conversion of chlorophyll a into chlorophyll b.     

A second nitrogenase-like enzyme for bacteriochlorophyll biosynthesis: reconstitution of chlorophyllide a reductase with purified X-protein (BchX) and YZ-protein (BchY-BchZ) from Rhodobacter capsulatus

In most photosynthetic organisms, the chlorin ring structure of chlorophyll a is formed by the reduction of the porphyrin D-ring by the dark-operative nitrogenase-like enzyme, protochlorophyllide reductase (DPOR). Subsequently, the chlorin B-ring is reduced in bacteriochlorophyll biosynthesis to form a bacteriochlorin ring structure. Phenotypic analysis of mutants lacking one of three genes, bchX, bchY, or bchZ, which show significant sequence similarity to the structural genes of nitrogenase, suggests that a second nitrogenase-like enzyme is involved in the chlorin B-ring reduction. However, there is no biochemical evidence for this. Here, we report the reconstitution of chlorophyllide a reductase (COR) with purified proteins. Two Rhodobacter capsulatus strains that overexpressed Strep-tagged BchX and BchY were isolated. Strep-tagged BchX was purified as a single polypeptide, and BchZ was co-purified with Strep-tagged BchY. When BchX and BchY-BchZ components were incubated with chlorophyllide a, ATP, and dithionite under anaerobic conditions, chlorophyllide a was converted to a new pigment with a Qy band of longer wavelength at 734 nm (P734) in 80% acetone. The formation of P734 was dependent on ATP and dithionite. High performance liquid chromatography and mass spectroscopic analysis indicated that P734 is 3-vinyl bacteriochlorophyllide a, which is formed by the B-ring reduction of chlorophyllide a. These results demonstrate that the B-ring of chlorin is reduced by a second nitrogenase-like enzyme and that the sequential actions of two nitrogenase-like enzymes, DPOR and COR, convert porphyrin to bacteriochlorin. The evolutionary implications of nitrogenase-like enzymes to determine the ring structure of (bacterio)chlorophyll pigments are discussed.     

Chloroplast Biogenesis 49 : Differences among Angiosperms in the Biosynthesis and Accumulation of Monovinyl and Divinyl Protochlorophyllide during Photoperiodic Greening

Various angiosperms differed in their monovinyl and divinyl protochlorophyllide biosynthetic capabilities during the dark and light phases of photoperiodic growth. Some plant species such as Cucumis sativus L., Brassica juncea (L.) Coss., Brassica kaber (DC.) Wheeler, and Portulaca oleracea L. accumulated mainly divinyl protochlorophyllide at night. Monocotyledonous species such as Avena sativa L., Hordeum vulgare L., Triticum secale L., Zea mays L., and some dicotyledonous species such as Phaseolus vulgaris L., Glycine max (L.) Merr., Chenopodium album L., and Lycopersicon esculentum L. accumulated mainly monovinyl protochlorophyllide at night.

Under low light intensities meant to simulate the first 60 to 80 minutes following daybreak divinyl protochlorophyllide appeared to contribute much more to chlorophyll formation than monovinyl protochlorophyllide in species such as Cucumis sativus L. Under the same light conditions, species which accumulated mainly monovinyl protochlorophyllide at night appeared to form chlorophyll preferably via monovinyl protochlorophyllide.

These results were interpreted in terms of: (a) a differential contribution of monovinyl and divinyl protochlorophyllide to chlorophyll formation at daybreak in various plant species; and (b) a differential regulation of the monovinyl and divinyl protochlorophyllide biosynthetic routes by light and darkness.

     

The major route for chlorophyll synthesis includes [3,8-divinyl]-chlorophyllide a reduction in Arabidopsis thaliana

In most reviews on Chl biosynthesis, Chl is described as being synthesized via the route involving the reduction of [3,8-divinyl]-protochlorophyllide a. However, the possibility remains that the conversion of the divinyl form of the Chl intermediate to its monovinyl form takes place at other enzymatic steps. To determine the actual route of Chl biosynthesis, we examined the substrate specificity of the formerly named [3,8-divinyl]-protochlorophyllide a 8-vinyl reductase (DVR) in vitro. In addition, we investigated the accumulation of various Chl intermediates in etiolated seedlings in vivo. Collectively, these studies indicate that [3,8-divinyl]-chlorophyllide a is the major substrate of DVR.     

Reconstitution of chlorophyllide formation by isolated etioplast membranes.

1. The reconstitution of chlorophyllide biosynthesis by barley etioplast membranes is described. 2. The process is dependent on the additon of NADPH and protochlorophyllide and on illumination, which can be either continuous or intermittent. 3. The reconstituted process involves spectroscopically similar intermediates to the native reaction in whole leaves. 4. Steps in the process are an initial enzymic formation in the dark of a photoactive complex, P638/652 (probably a ternary protochlorophyllide-NADPH-enzyme complex), followed by a very rapid light-dependent hydrogen transfer from the NADPH to the protochlorophyllide giving chlorophyllide giving chlorophyllide, finally releasing the enzyme for repeating the process. 5. A continuous assay for the system regenerating complex P638/652 was devised on the basis of monitoring chlorophyllide formation. 6. The pH optimum of the reaction is at 6.9 and Km values for protochlorophyllide and NADPH are 0.46 and 35 micron respectively. 7. The reaction is associated specifically with the etioplast membrane fraction. 8. Activities of the system assayed in vitro are more than adequate to account for rates of chlorophyll formation in vivo.     

Chloroplast biogenesis 51 : modulation of monovinyl and divinyl protochlorophyllide biosynthesis by light and darkness in vitro

It is shown that the monovinyl and divinyl protochlorophyllide biosynthetic patterns of etiolated maize (Zea mays L.), and cucumber (Cucumis sativus L.) seedlings and of their isolated etiochloroplasts can be modulated by light and darkness as was shown for green photoperiodically grown plants (E. E. Carey, C. A. Rebeiz 1985 Plant Physiol. 79: 1-6). In etiolated corn and cucumber seedlings and isolated etiochloroplasts poised in the divinyl protochlorophyllide biosynthetic mode by a 2 hour light pretreatment, darkness induced predominantly the biosynthesis of monovinyl protochlorophyllide in maize and of divinyl protochlorophyllide in cucumber. When etiolated seedlings and their isolated etiochloroplasts were poised in the monovinyl protochlorophyllide biosynthetic mode by a prolonged dark-pretreatment, light induced mainly the biosynthesis of divinyl protochlorophyllide in both maize and cucumber.     

Identification of a novel vinyl reductase gene essential for the biosynthesis of monovinyl chlorophyll in Synechocystis sp. PCC6803

The vast majority of oxygenic photosynthetic organisms use monovinyl chlorophyll for their photosynthetic reactions. For the biosynthesis of this type of chlorophyll, the reduction of the 8-vinyl group that is located on the B-ring of the macrocycle is essential. Previously, we identified the gene encoding 8-vinyl reductase responsible for this reaction in higher plants and termed it DVR. Among the sequenced genomes of cyanobacteria, only several Synechococcus species contain DVR homologues. Therefore, it has been hypothesized that many other cyanobacteria producing monovinyl chlorophyll should contain a vinyl reductase that is unrelated to the higher plant DVR. To identify the cyanobacterial gene that is responsible for monovinyl chlorophyll synthesis, we developed a bioinformatics tool, correlation coefficient calculation tool, which calculates the correlation coefficient between the distributions of a certain phenotype and genes among a group of organisms. The program indicated that the distribution of a gene encoding a putative dehydrogenase protein is best correlated with the distribution of the DVR-less cyanobacteria. We subsequently knocked out the corresponding gene (Slr1923) in Synechocystis sp. PCC6803 and characterized the mutant. The knock-out mutant lost its ability to synthesize monovinyl chlorophyll and accumulated 3,8-divinyl chlorophyll instead. We concluded that Slr1923 encodes the vinyl reductase or a subunit essential for monovinyl chlorophyll synthesis. The function and evolution of 8-vinyl reductase genes are discussed.     

With chlorophyll pigments from prolamellar bodies to light-harvesting complexes

The biosynthetic chain leading from 5-aminolevulinic acid to chlorophyll is localised to the plastid. Many of the enzymes are nuclear-encoded. NADPH-protochlorophyllide oxidoreductase (EC 1.3.1.33) is one such enzyme which is encoded by two different genes and can exist in an A and a B form. Its import into the plastid seems to be facilitated when protochlorophyllide is present in the chloroplast envelope. Within the plastid the reductase is assembled to thylakoids or prolamellar bodies. The specific properties of the reductase together with the specific properties of the lipids present in the etioplast inner membranes promote the formation of the three-dimensional regular network of the prolamellar bodies. The reductase forms a ternary complex with protochlorophyllide and NADPH that gives rise to different spectral forms of protochlorophyllide. Light transforms protochlorophyllide into chlorophyllide and this photoreaction induces a conformational change in the reductase protein which leads to a process of disaggregation of enzyme, pigment aggregates and membranes, which can be followed spectroscopically and with electron microscopy. The newly formed chlorophyllide is esterified by a membrane-bound nuclear-encoded chlorophyll synthase and the chlorophyll molecule is then associated with proteins into active pigment protein complexes in the photosynthetic machinery.     

Envelope membranes from mature spinach chloroplasts contain a NADPH:protochlorophyllide reductase on the cytosolic side of the outer membrane

Using fluorescence spectroscopy, we have demonstrated that isolated envelope membranes from mature spinach chloroplasts catalyze the phototransformation of endogenous protochlorophyllide into chlorophyllide in presence of NADPH, but not in presence of NADH. Protochlorophyllide reductase was characterized further using monospecific antibodies (anti-protochlorophyllide reductase) raised against the purified enzyme from oat. In mature spinach chloroplasts, protochlorophyllide reductase is present only in envelope membranes. We have demonstrated that the envelope protochlorophyllide reductase, a 37,000-dalton polypeptide, is only a minor envelope component and is present on the outer surface of the outer envelope membrane. This conclusion is supported by several lines of evidence: (a) the envelope polypeptide that was immunodecorated with anti-protochlorophyllide reductase can be distinguished from the major 37,000-dalton envelope polypeptide E37 (which was identified by monospecific antibodies) only after two-dimensional polyacrylamide gel electrophoresis; (b) the envelope protochlorophyllide reductase was hydrolyzed when isolated intact chloroplasts were incubated in presence of thermolysin; and (c) isolated intact chloroplasts strongly agglutinate when incubated in presence of antibodies raised against protochlorophyllide reductase. These results demonstrate that major differences exist between chloroplasts and etioplasts with respect to protochlorophyllide reductase levels and localization. The presence on the chloroplast envelope membrane of both the substrate (protochlorophyllide) and the enzyme (protochlorophyllide reductase) necessary for chlorophyllide synthesis could have major implications for the understanding of chlorophyll biosynthesis in mature chloroplasts.     

Identification of the Main Species of Tetrapyrrolic Pigments in Envelope Membranes from Spinach Chloroplasts

The chlorophyll precursors protochlorophyllide and chlorophyllide were identified in purified envelope membranes from spinach (Spinacia oleracea) chloroplasts. This was shown after pigment separation by high performance liquid chromatography (HPLC) using specific fluorescence detection for these compounds. Protochlorophyllide and chlorophyllide concentrations in envelope membranes were in the range of 0.1 to 1.5 nmol/mg protein. Chlorophyll content of the envelope membranes was extremely low (0.3 nmol chlorophyll a/mg protein), but the molar ratios of protochlorophyllide and chlorophyllide to chlorophyll were 100 to 1000 times higher in envelope membranes than in thylakoid membranes. Therefore, envelope tetrapyrrolic pigments consist in large part (approximately one-half) of nonphytylated molecules, whereas only 0.1% of the pigments in thylakoids are nonphytylated molecules. Clear-cut separation of protochlorophyllide and chlorophyllide by HPLC allowed us to confirm the presence of a slight protochlorophyllide reductase activity in isolated envelope membranes from fully developed spinach chloroplasts. The enzyme was active only when envelope membranes were illuminated in the presence of NADPH.