Assembly of the D1 precursor in monomeric photosystem II reaction center precomplexes precedes chlorophyll a-triggered accumulation of reaction center II in barley etioplasts

Assembly of plastid-encoded chlorophyll binding proteins of photosystem II (PSII) was studied in etiolated barley seedlings and isolated etioplasts and either the absence or presence of de novo chlorophyll synthesis. De novo assembly of reaction center complexes in etioplasts was characterized by immunological analysis of protein complexes solubilized from inner etioplast membranes and separated in sucrose density gradients. Previously characterized membrane protein complexes from chloroplasts were utilized as molecular mass standards for sucrose density gradient separation analysis. In etiolated seedlings, induction of chlorophyll a synthesis resulted in the accumulation of D1 in a dimeric PSII reaction center (RCII) complex. In isolated etioplasts, de novo chlorophyll a synthesis directed accumulation of D1 precursor in a monomeric RCII precomplex that also included D2 and cytochrome b(559). Chlorophyll a synthesis that was chemically prolonged in darkness neither increased the yield of RCII monomers nor directed assembly of RCII dimers in etioplasts. We therefore conclude that in etioplasts, assembly of the D1 precursor in monomeric RCII precomplexes precedes chlorophyll a-triggered accumulation of reaction center monomers.     

Carotenoid and chlorophyll biosynthesis in isolated plastids from mustard seedling cotyledons (Sinapis alba L.) during etioplast-chloroplast conversion

Etioplasts and etiochloroplasts, isolated from seedlings of white mustard (Sinapis alba L.) grown in continuous far-red light, and chloroplasts isolated from cotyledons and primary leaves of white-light-grown seedlings exhibit high prenyl-lipid-forming activities. Only the etioplasts and etiochloroplasts, and to a much lesser extent chloroplasts from cotyledons are capable of forming carotenes from isopentenyl diphosphate as substrate, whereas in chloroplasts from primary leaves no such activities could be detected. By subfractionation experiments, it could be demonstrated that the phytoene-synthase complex in etioplasts and etiochloroplasts is present in a soluble form in the stroma, whereas the subsequent enzymes, i.e. the dehydrogenase, cis-trans isomerase and cyclase are bound to both membrane fractions, the prolamellar bodies/prothylakoids and the envelopes. In good agreement with previous results using isolated chromoplasts and chloroplasts, it is concluded that the phytoene-synthase complex may change its topology from a peripheral membrane protein in non-green plastids to a tightly membrane-associated protein in chloroplasts. This change is apparently paralleled by altered functional properties which render the complex undetectable in isolated chloroplasts. Further experiments concerning the reduction of chlorophyll a containing a geranylgeranyl side chain to chlorophyll a indicate that the light-induced etioplast-chloroplast conversion is accompanied by a certain reorganization of the polyprenoid-forming enzymatic equipment.Abbreviations Chl a chlorophyll a - Chl_GG chlorophyll a containing a geranylgeranyl side chain - HPLC high-performance liquid chromatography - Tris 2-ammo-2-(hydroxymethyl)-1,3-propanediol     

Expression of protein complexes and individual proteins upon transition of etioplasts to chloroplasts in pea (Pisum sativum)

The protein complexes of pea (Pisum sativum L.) etioplasts,etio-chloroplasts and chloroplasts were examined using 2D BlueNative/SDS–PAGE. The most prominent protein complexesin etioplasts were the ATPase and the Clp and FtsH proteasecomplexes which probably have a crucial role in the biogenesisof etioplasts and chloroplasts. Also the cytochrome b₆f (Cytb₆f) complex was assembled in the etioplast membrane, as wellas Rubisco, at least partially, in the stroma. These complexesare composed of proteins encoded by both the plastid and nucleargenomes, indicating that a functional cross-talk exists betweenpea etioplasts and the nucleus. In contrast, the proteins andprotein complexes that bind chlorophyll, with the PetD subunitand the entire Cyt b₆f complex as an exception, did not accumulatein etioplasts. Nevertheless, some PSII core components suchas PsbE and the luminal oxygen-evolvong complex (OEC) proteinsPsbO and PsbP accumulated efficiently in etioplasts. After 6h de-etiolation, a complete PSII core complex appeared with40% of the maximal photochemical efficiency, but a fully functionalPSII was recorded only after 24 h illumination. Similarly, thecore complex of PSI was assembled after 6 h illumination, whereasthe PSI–light-harvesting complex I was stably assembledonly in chloroplasts illuminated for 24 h. Moreover, a batteryof proteins responsible for defense against oxidative stressaccumulated particularly in etioplasts, including the stromaland thylakoidal forms of ascorbate peroxidase, glutathione reductaseand PsbS.     

Cytochrome b6f is a dimeric protochlorophyll a binding complex in etioplasts

The cytochrome b6f complex is a dimeric protein complex that is of central importance for photosynthesis to carry out light driven electron and proton transfer in chloroplasts. One molecule of chlorophyll a was found to associate per cytochrome b6f monomer and the structural or functional importance of this is discussed. We show that etioplasts which are devoid of chlorophyll a already contain dimeric cytochrome b6f. However, the phytylated chlorophyll precursor protochlorophyll a, and not chlorophyll a, is associated with subunit b6. The data imply that a phytylated tetrapyrrol is an essential structural requirement for assembly of cytochrome b6f.     

Behavior of the 36,000-dalton Protein in the Internal Membranes of Squash Etioplasts during Greening

The 36,000-dalton protein was found to be a major componentin the internal membrane of etioplasts of dark-grown squashcotyledons by slab SDS-polyacrylamide gel electrophoresis. Itwas also a major membrane protein of the etioplast in otheretiolated plants such as oat and maize. When the etioplastswere transformed into (etio)chloroplasts under continued illumination,depletion of the 36,000-dalton protein began without a lag timefollowed by their disappearance, while formation of apoproteinsof the light-harvesting chlorophyll protein complex, 26,000-and 22,400-dalton proteins, was noted. A 55,000-dalton proteinwas also present and its content did not change during greening.O'Farrell's two-dimensional electrophoresis revealed that the36,000-dalton protein consisted of at least four alkaline proteinsof the same molecular weight but with different isoelectricpoints of 9.1, 8.8, 8.5 and 8.2. They were found to be verysimilar protein by partial proteolysis using staphylococcalprotease. The two-dimensional electrophoresis pattern of the36,000-dalton protein was altered after 1 hr illumination. Thesebehaviors of the 36,000-dalton protein during the greening processwere accompanied by transformation of the crystalline prolamellarbody in the etioplast. (Received September 16, 1981; Accepted March 15, 1982)     

Chlorophyll synthetase is latent in well preserved prolamellar bodies of etiolated wheat

Membrane fractions containing intact etioplasts, etioplast inner membranes, prolamellar bodies or prothylakoids from wheat ( Triticum aestivum L. cv. Walde) were assayed for chlorophyll synthetase activity. Calculated on a protein basis, the etioplast inner membrane fraction showed a higher activity than the intact etioplasts. The activity was higher in the prolamellar body fraction than in the prothylakoid fraction. However, when the fractions were incubated in isolation medium with 50% (w/w) sucrose and 0.3 m M NADPH, chlorophyll synthetase activity could not be detected in the prolamellar body fraction, while the prothylakoid fraction maintained a high activity. The spectral shift to a shorter wavelength of the newly formed endogenous chlorophyllide was very rapid in the prothylakoid fraction but slow in the prolamellar body fraction. The relation between the spectral shift of chlorophyllide and the esterification activity in the fractions is discussed. Even exogenous short-wavelength chlorophyllide could not be esterified in well preserved prolamellar bodies. This indicates that chlorophyll synthetase is present in an inactive state in the prolamellar body structure. A large-scale method for the synthesis of geranylgeranylpyrophosphate, one of the substrates of the chlorophyll synthetase reaction, is also presented.     

Comparison of the Molecular Weights of Proteins Synthesized by Isolated Chloroplasts with Those Which Appear during Greening in Zea mays

The proteins of prolamellar bodies of etioplasts and of thylakoid membranes of greening and mature chloroplasts from Zea mays were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three classes of proteins were distinguished: those present in etioplasts and disappearing during greening, those absent in etioplasts and appearing during greening, and those present in both etioplasts and chloroplasts. The largest number of proteins belonged to this last class.The molecular weights of chloroplast thylakoid proteins were compared to the molecular weights of the membrane-associated proteins synthesized by isolated, mature chloroplasts. Thirteen of the 15 to 20 membrane-bound proteins made by isolated chloroplasts corresponded in size to proteins present in chloroplasts. Most of the 13 are present in both etioplasts and chloroplasts although a few were the same size as proteins which increase during greening. Production of most of the membrane proteins made in the plastids is not stringently regulated by light in vivo. The polypeptide subunits of the light-harvesting pigment-protein complex, the most abundant proteins of the chloroplast thylakoids, were absent from etioplasts. They were not synthesized by isolated chloroplasts.     

Expression of genes for plastid membrane proteins in barley under intermittent light conditions

Barley plants grown under intermittent light show a plastid membrane composition intermediate between those of etioplasts and chloroplasts. In particular protochlorophyll reductase disappears from the membranes whereas the 32000 protein, coded for by chloroplast DNA, becomes integrated into the membranes. The light-harvesting chlorophyll a/b protein does not accumulate within the membranes even after 11 d of development, while the corresponding mRNA can already be observed after 4 d and is translated under in vivo conditions.Abbreviations LHCP light-harvesting chlorophyll a/b protein - IL intermittent light - LD light-dark (12-h day) - EGTA ethyleneglycol-bis(oxy-ethylenenitrile)tetraacetic acid     

Protochlorophyllide b does not occur in barley etioplasts

Barley (Hordeum vulgare L.) etioplasts were isolated, and the pigments were extracted with acetone. The extract was analyzed by HPLC. Only protochlorophyllide a and no protochlorophyllide b was detected (limit of detection < 1% of protochlorophyllide a). Protochlorophyllide b was synthesized starting from chlorophyll b and incubated with etioplast membranes and NADPH. In the light, photoconversion to chlorophyllide b was observed, apparently catalyzed by NADPH :protochlorophyllide oxidoreductase. In darkness, reduction of the analogue zinc protopheophorbide b to zinc 7-hydroxy-protopheophorbide a was observed, apparently catalyzed by chlorophyll b reductase. We conclude that protochlorophyllide b does not occur in detectable amounts in etioplasts, and even traces of it as the free pigment are metabolically unstable. Thus the direct experimental evidence contradicts the idea by Reinbothe et al. (Nature 397 (1999) 80-84) of a protochlorophyllide b-containing light-harvesting complex in barley etioplasts.     

Some observations on chlorophyll(ide) synthesis by isolated etioplasts.

1. A modified procedure for the isolation of etioplasts from dark-grown barley is described and the regeneration of phototransformable protchlorophyll(ide) was demonstrated in the isolated plastids. 2. On exposure of the etioplasts to a long-term flash illumination, chlorophyll(ide) synthesis from a precursor pool, which includes all the protochlorophyllide, was demonstrated. 3. Added delta-aminolaevulinic acid failed to be significantly incorporated into chlorophyll(ide) in the etioplasts despite its extensive incorporation into porphyrin precursors of chlorophyll and haem compounds. The findings are discussed in terms of the inability of etioplasts to carry out the metal-insertion step in chlorophyll synthesis. 4. An elevated chlorophyll(ide) concentration was attained in the etioplasts by increasing the size of the utilizable precursor pool by pre-feeding whole plants with delta-aminolaevulinic acid, isolating the etioplasts and subjecting them to the flash illumination.     

An efficient and prolonged in vitro translational system from isolated cucumber etioplasts

Etioplasts were isolated from dark grown cucumber cotyledons pretreated with kinetin and gibberellic acid. When incubated in a cofactor enriched medium these etioplasts incorporated [35S] methionine into a hot trichloroacetic acid-insoluble fraction; this incorporation was linear for 8 h of incubation and was inhibited by chloramphenicol but not by cycloheximide. Over the same time period, the etioplasts showed continued linear synthesis of the chlorophyll precursors protochlorophyllide, Mg-protoporphyrin and protoporphyrin IX. Analysis of products of in vitro protein synthesis by etioplasts and cotyledons showed the thylakoid membrane polypeptide profiles to be identical. Continued incorporation of [35S] methionine into the large subunit of ribulose bisphosphate carboxylase/oxygenase (RuBisCO) for 8 h has been confirmed further by immunoprecipitation with anti-spinach RuBisCO. This competent in vitro translation system should be useful for future studies of chloroplast protein synthesis and gene expression.     

Pigment-free NADPH:protochlorophyllide oxidoreductase from Avena sativa L. Purification and substrate specificity.

The enzyme NADPH:protochlorophyllide oxidoreductase (POR) is the key enzyme for light-dependent chlorophyll biosynthesis. It accumulates in dark-grown plants as the ternary enzyme-substrate complex POR-protochlorophyllide a-NADPH. Here, we describe a simple procedure for purification of pigment-free POR from etioplasts of Avena sativa seedlings. The procedure implies differential solubilization with n-octyl-beta-D-glucoside and one chromatographic step with DEAE-cellulose. We show, using pigment and protein analysis, that etioplasts contain a one-to-one complex of POR and protochlorophyllide a. The preparation of 13 analogues of protochlorophyllide a is described. The analogues differ in the side chains of the macrocycle and in part contain zinc instead of the central magnesium. Six analogues with different side chains at rings A or B are active substrates, seven analogues with different side chains at rings D or E are not accepted as substrates by POR. The kinetics of the light-dependent reaction reveals three groups of substrate analogues with a fast, medium and slow reaction. To evaluate the kinetic data, the molar extinction coefficients in the reaction buffer had to be determined. At concentrations above 2 mole substrate/mole enzyme, inhibition was found for protochlorophyllide a and for the analogues.     

Biogenesis,assembly and turnover of photosystem II units

Assembly of photosystem II, a multiprotein complex embedded in the thylakoid membrane, requires stoichiometric production of over 20 protein subunits. Since part of the protein subunits are encoded in the chloroplast genome and part in the nucleus, a signalling network operates between the two genetic compartments in order to prevent wasteful production of proteins. Coordinated synthesis of proteins also takes place among the chloroplast-encoded subunits, thus establishing a hierarchy in the protein components that allows a stepwise building of the complex. In addition to this dependence on assembly partners, other factors such as the developmental stage of the plastid and various photosynthesis-related parameters exert a strict control on the accumulation, membrane targeting and assembly of the PSII subunits. Here, we briefly review recent results on this field obtained with three major approaches: biogenesis of photosystem II during the development of chloroplasts from etioplasts, use of photosystem II-specific mutants and photosystem II turnover during its repair cycle.     

POR - import and membrane association of a key element in chloroplast development

The development of proplastids or etioplasts to chloroplast is visualized by the accumulation of chlorophyll in leaves of higher plants. The biosynthesis of chlorophyll includes a light-dependent reduction of protochlorophyllide (Pchlide) to chlorophyllide (Chlide). This light-dependent step is catalysed by the nucleus-encoded NADPH:Pchlide oxidoreductase (POR, EC 1.6.99.1). POR is active within plastids and therefore has to be translocated over the plastid envelope membranes. The import of chloroplast proteins seems to follow a general import pathway using translocons at the outer and inner envelope membrane. POR cross-linking to Toc75, one of the major translocon components at the outer envelope membrane, indicates its use of the general import pathway. However, since variations exist within the so-called general import pathway one has to consider previous data suggesting a novel totally Pchlide-dependent import pathway of one POR isoform, PORA. The suggested Pchlide dependency of POR import is discussed since recent observations contradict this idea. In the stroma the POR transit peptide is cleaved off and the mature POR protein is targeted to the plastid inner membranes. The correct and stable association of POR to the membrane requires the cofactor NADPH. Functional activity of POR calls for formation of an NADPH–Pchlide–POR complex, a formation that probably takes place after the membrane association and is dependent on a phosphorylation reaction.     

Tentoxin does not cause chlorosis in greening mung bean leaves by inhibiting photophosphorylation

Effects of the fungal toxin, tentotoxin, on development and chlorophyll accumulation of plastids of primary leaves of mung bean [ Vigna radiata (L.) Wilczek cv. Berken] were studied using spectrophotometric, electrophoretic, and microscopic procedures. In etioplasts of control tissues both prolamellar bodies and prothylakoids occurred, whereas small vesicles were associated with structurally distinct prolamellar bodies in tentoxin-affected etioplasts. As determined by in vivo spectrophotometry, tentoxin-affected etioplasts had 25% less phototransformable protochlorophyll(ide) and 35% less non-phototransformable protochlorophyll(ide) than had control etioplasts after 5 days of dark seedling growth. Tentoxin had no effect on the rate of the Shibita shift. Protochlorophyll(ide) resynthesis in the dark immediately after protochlorophyll(ide) phototransformation was five to six times slower in tentoxintreated than in control tissues. Effects on chlorophyll(ide) content were observed within 30 min of the beginning of continuous white light exposure. In vivo measurement of cytochrome f redox activity revealed that this cytochrome was linked to light-driven electron flow in control tissues within 20 min of the beginning of continuous white light, whereas in the tentoxin-treated tissues there was no linkage (despite the presence of cytochrome f ) at any time. Coupling factor 1 was present and had potential ATPase activity in both control and tentoxin-affected plastids. There was about sixteen times more chlorophyll in control than in tentoxin-treated tissues in continuous as well as in intermittent (2 min light/118 min dark) light. These data are consistent with the view that tentoxin disrupts normal etioplast and chloroplast development through a mechanism unrelated to photophosphorylation.     

The in vitro assembly of the NADPH-protochlorophyllide oxidoreductase in pea chloroplasts

The NADPH-protochlorophyllide oxidoreductase (pchlide reductase, EC 1.6.99.1) is the major protein in the prolamellar bodies (PLBs) of etioplasts, where it catalyzes the light-dependent reduction of protochlorophyllide to chlorophyllide during chlorophyll synthesis in higher plants. The suborganellar location in chloroplasts of light-grown plants is less clear. In vitro assays were performed to characterize the assembly process of the pchlide reductase protein in pea chloroplasts. Import reactions employing radiolabelled precursor protein of the pchlide reductase showed that the protein was efficiently imported into fully matured green chloroplasts of pea. Fractionation assays following an import reaction revealed that imported protein was targeted to the thylakoid membranes. No radiolabelled protein could be detected in the stromal or envelope compartments upon import. Assembly reactions performed in chloroplast lysates showed that maximum amount of radiolabelled protein was associated to the thylakoid membranes in a thermolysin-resistant conformation when the assays were performed in the presence of hydrolyzable ATP and NADPH, but not in the presence of NADH. Furthermore, membrane assembly was optimal at pH 7.5 and at 25°C. However, further treatment of the thylakoids with NaOH after an assembly reaction removed most of the membrane-associated protein. Assembly assays performed with the mature form of the pchlide reductase, lacking the transit peptide, showed that the pre-sequence was not required for membrane assembly. These results indicate that the pchlide reductase is a peripheral protein located on the stromal side of the membrane, and that both the precursor and the mature form of the protein can act as substrates for membrane assembly.     

Implications of a Developmental-Stage-Dependent Thylakoid-Bound Protease in the Stabilization of the Light-Harvesting Pigment-Protein Complex Serving Photosystem II during Thylakoid Biogenesis in Red Kidney Bean

Intact etioplasts of bean (Phaseolus vulgaris) plants exhibit proteolytic activity against the exogenously added apoprotein of the light-harvesting pigment-protein complex serving photosystem II (LHCII) that increases as etiolation is prolonged. The activity increases in the membrane fraction but not in the stroma, where it remains low and constant and is mainly directed against LHCII and protochlorophyllide oxidoreductase. The thylakoid proteolytic activity, which is low in etioplasts of 6-d-old etiolated plants, increases in plants pretreated with a pulse of light or exposed to intermittent-light (ImL) cycles, but decreases during prolonged exposure to continuous light, coincident with chlorophyll (Chl) accumulation. To distinguish between the control of Chl and/or development on proteolytic activity, we used plants exposed to ImL cycles of varying dark-phase durations. In ImL plants exposed to an equal number of ImL cycles with short or long dark intervals (i.e. equal Chl accumulation but different developmental stage) proteolytic activity increased with the duration of the dark phase. In plants exposed to ImL for equal durations to such light-dark cycles (i.e. different Chl accumulation but same developmental stage) the proteolytic activity was similar. These results suggest that the protease, which is free to act under limited Chl accumulation, is dependent on the developmental stage of the chloroplast, and give a clue as to why plants in ImL with short dark intervals contain LHCII, whereas those with long dark intervals possess only photosystem-unit cores and lack LHCII.     

Chlorophyll biosynthesis by mesophyll protoplasts and plastids from etiolated oat (Avena sativa L.) leaves

The uptake of [1-³H]geranylgeranyl diphosphate (GGPP) into protoplasts and intact etioplasts and the metabolic interconversion therein was studied after a 2 min pulse of white light. The chlorophyll synthetase reaction, Chlide+GGPPChl_GG, was taken as a natural probe for the etioplast compartment. This reaction yields labeled ChL_GG and, by hydrogenation, labeled Chl_P, when [1-³H]GGPP receives access to the etioplast stroma. It was found that penetration across the plastid envelope was rapid and that penetration across the plasma membrane of protoplasts, however, was slow. A cellular pool of soluble GGPP was detected. This pool was lost, in part, during preparation of the protoplasts and almost completely during preparation of the etioplasts. The membrane-bound phytol pool of etioplasts could not be replaced by exogenous [³H]GG. The endogenous GG and phytol pools of protoplasts, which were larger than those of etioplasts, could be replaced in part by exogenous [³H]GGPP. That part of this pool exists as soluble GGPP or as a direct precursor in the cytoplasm is discussed.Abbreviations GGPP geranylgeranyldiphosphate - Chl_GG geranylgeranyl chlorophyllide a - Chl_P phytyl chlorophyllide a - IPP isopentenyl diphosphate - Chlide chlorophyllide a     

Biogenesis of water splitting by photosystem II during de‐etiolation of barley (Hordeum vulgare L.)

Etioplasts lack thylakoid membranes and photosystem complexes. Light triggers differentiation of etioplasts into mature chloroplasts, and photosystem complexes assemble in parallel with thylakoid membrane development. Plastids isolated at various time points of de‐etiolation are ideal to study the kinetic biogenesis of photosystem complexes during chloroplast development. Here, we investigated the chronology of photosystem II (PSII) biogenesis by monitoring assembly status of chlorophyll‐binding protein complexes and development of water splitting via O₂ production in plastids (etiochloroplasts) isolated during de‐etiolation of barley (Hordeum vulgare L.). Assembly of PSII monomers, dimers and complexes binding outer light‐harvesting antenna [PSII‐light‐harvesting complex II (LHCII) supercomplexes] was identified after 1, 2 and 4 h of de‐etiolation, respectively. Water splitting was detected in parallel with assembly of PSII monomers, and its development correlated with an increase of bound Mn in the samples. After 4 h of de‐etiolation, etiochloroplasts revealed the same water‐splitting efficiency as mature chloroplasts. We conclude that the capability of PSII to split water during de‐etiolation precedes assembly of the PSII‐LHCII supercomplexes. Taken together, data show a rapid establishment of water‐splitting activity during etioplast‐to‐chloroplast transition and emphasize that assembly of the functional water‐splitting site of PSII is not the rate‐limiting step in the formation of photoactive thylakoid membranes.