In vitro synthesis and assembly of photosystem II proteins of spinach chloroplasts

The synthesis and assembly of photosystem II (PS II) proteins of spinach chloroplasts were investigated in three different in vitro systems, i.e., protein synthesis in isolated chloroplasts (in organello translation), read-out translation of thylakoid-bound ribosomes, and transport of translation products from spinach leaf polyadenylated RNA into isolated chloroplasts. Polyacrylamide gel electrophoresis of labeled thylakoid polypeptides in the presence of sodium dodecyl sulfate revealed that the first two systems were capable of synthesizing the reaction center proteins of PS II (47 and 43 kDa), the herbicide-binding protein, and cytochrome b559. The reaction center proteins synthesized in organello were shown to bind chlorophyll and to assemble properly into the PS II core complex. One of the reaction center proteins translated by the thylakoid-bound ribosomes (47 kDa) was also found to be integrated in situ into the complex but was lacking bound chlorophyll. Incorporation of radioactivity into the three extrinsic proteins of the oxygen-evolution system (33, 24, and 18 kDa) was detected only when intact chloroplasts were incubated with the translation products from polyadenylated RNA, showing that these proteins are coded for by nuclear DNA. The occurrence of a precursor polypeptide 6 kDa larger than the 33-kDa protein was immunochemically detected in the translation products.     

Synthesis and assembly of H+-ATPase complex by isolated "rough" thylakoids

The synthesis and assembly of chloroplast H+-ATPase complex were studied by analyzing the incorporation of [35S]methionine into the constituent subunits with isolated intact chloroplasts and with thylakoid membranes that had been prepared from the chloroplasts so that they would retain ribosomes. The complex was isolated from thylakoids after labeling and identified by immunoprecipitation with an antiserum specific to CF1. The mechanism for the assembly of the complex was demonstrated to be active in the isolated chloroplasts by the following observations: the plastid genome-regulated subunits (alpha, beta, epsilon, I, and III) were labeled by in organello translation and recovered with the complex, and three other subunits (gamma, delta, and II) were labeled when intact chloroplasts were incubated with translation products from polyadenylated RNA. The two largest subunits, alpha and beta, were translated on thylakoid-bound ribosomes when the thylakoid membranes were incubated with soluble factors from Escherichia coli. They were recovered with the H+-ATPase complex, suggesting that they are translated on the bound ribosomes in the chloroplast, and that the isolated membranes retain the ability to assemble a complete complex. Provided that these observations are the result of de novo assembly of the complex, the imported and processed nuclear-coded subunits are presumed to be pooled not in stroma but on the membrane.     

Photosystem I reaction center polypeptides of spinach are synthesized on thylakoid-bound ribosomes

Purified chloroplasts were prepared from developing spinach leaves. The chloroplasts were separated into thylakoid and stroma fractions, and nucleic acids were prepared from them. Photosystem I reaction center polypeptide(s) (PS I RC) mRNA was associated with the thylakoid fraction when measured by hybridization using a probe for PS I RC polypeptide ps1A1, or when measured by translation assay. The ps1A1 polypeptide was coded for by a 5.5-kbp mRNA which others have shown also codes for PS IRC polypeptide ps1A2. This mRNA was in functional thylakoid-bound ribosomes because when thylakoids with bound ribosomes were translated in the absence of protein synthesis initiation, polypeptides that reacted with anti-PS I RC were formed. The results indicate that PS I RC polypeptides are synthesized exclusively by thylakoid-bound ribosomes.     

Synthesis of large subunit of ribulosebisphosphate carboxylase by thylakoid-bound polyribosomes from spinach chloroplasts

Intact chloroplasts were isolated from developing first leaves of spinach. The chloroplasts were broken and separated into an extensively washed membrane (thylakoid) fraction and a soluble (stroma) fraction. The membrane fraction contained polyribosomes with properties similar to those of thylakoid-bound polyribosomes of other organisms. The distribution of mRNA for large-subunit ribulosebisphosphate carboxylase (LS) was determined by translating RNA from chloroplasts, thylakoids, and stroma in a wheat germ cell-free translation system. LS translation product was identified by immunoprecipitation with antibody to LS from spinach, electrophoresis of the immunoprecipitated product, and fluorography. At least 44% of translatable chloroplast LS-mRNA was in the washed thylakoid fraction. Thylakoid-bound LS-mRNA was in polyribosomes since LS was produced by thylakoids in an Escherichia coli cell-free translation system under conditions where initiation did not take place. Our results demonstrate that membrane-bound polyribosomes can synthesize the stroma-localized polypeptide LS, and suggest that the thylakoids may be an important site of its synthesis.     

Further characterization of ribosome binding to thylakoid membranes

Previous work indicated more polysomes bound to pea (Pisum sativum cv Progress No. 9) thylakoids in light than in the dark, in vivo (LE Fish, AT Jagendorf 1982 Plant Physiol 69: 814-825). With isolated intact chloroplasts incubated in darkness, addition of MgATP had no effect but 24 to 74% more RNA was thylakoid-bound at pH 8.3 than at pH 7. Thus, the major effect of light on ribosome-binding in vivo may be due to higher stroma pH. In isolated pea chloroplasts, initiation inhibitors (pactamycin and kanamycin) decreased the extent of RNA binding, and elongation inhibitors (lincomycin and streptomycin) increased it. Thus, cycling of ribosomes is controlled by translation, initiation, and termination. Bound RNA accounted for 19 to 24% of the total chloroplast RNA and the incorporation of [³H]leucine into thylakoids was proportional to the amount of this bound RNA. These data support the concept that stroma ribosomes are recruited into thylakoid polysomes, which are active in synthesizing thylakoid proteins.     

In-vitro translation of different mRNA-containing fractions of Chlamydomonas chloroplasts

Starting from isolated chloroplasts of the Chlamydomonas reinhardii cw 15 mutant, several mRNA-containing chloroplast subfractions, i.e. thylakoid-bound polysomes, detached polysomes or isolated RNA, were prepared and incubated in homologous and heterologous translation systems. In the reticulocyte lysate these fractions gave rise to strikingly different product patterns. A most prominent difference concerned the in-vivo rapidly labelled 32,000-dalton thylakoid polypeptide. Neither this membrane protein nor its 34,000-dalton precursor was formed when membrane-containing or free polysomes were translated, while the 34,000-dalton precursor was a main product of the RNA isolated from the same membranes. The influence of thylakoid membranes during translation was also observed in homologous translation systems with lysed chloroplasts supplemented with ATP. Membrane and soluble fractions, when translated separately, yielded product patterns which differed from each other, although the RNAs extracted from the respective fractions gave the same product patterns when translated in reticulocyte lysate; the latter included a soluble protein, the large subunit of ribulose-1,5-bisphosphate carboxylase, and a membrane protein, the 34,000-dalton precursor of the 32,000-dalton membrane protein, as major labelled translation products. These results point to a regulatory role of thylakoid membranes in the expression of chloroplast mRNA and argue against compartmentation of the chloroplast mRNAs between the soluble and membrane fractions.Abbreviation SDS sodium dodecyl sulfate     

Periodic variations in the ratio of free to thylakoid-bound chloroplast ribosomes during the cell cycle of Chlamydomonas reinhardtii

The ratio of free to thylakoid-bound chloroplast ribosomes in Chlamydomonas reinhardtii undergoes periodic changes during the synchronous light-dark cycle. In the light, when there is an increase in the chlorophyll content and synthesis of thylakoid membrane proteins, about 20-30% of the chloroplast ribosomes are bound to the thylakoid membranes. On the other hand, only a few or no bound ribosomes are present in the dark when there is no increase in the chlorophyll content. The ribosome-membrane interaction depends not only on the developmental stage of the cell but also on light. Thus, bound ribosomes were converted to the free variety after cultures at 4 h in the light had been transferred to the dark for 10 min. Conversely, a larger number of chloroplast ribosomes became attached to the membranes after cultures at 4 h in the dark had been illuminated for 10 min. Under normal conditions, when there was slow cooling of the cultures during cell harvesting, chloroplast polysomal runoff occurred in vivo leading to low levels of thylakoid-bound ribosomes. This polysomal runoff could be arrested by either rapid cooling of the cells or the addition of chloramphenicol or erythromycin. Each of these treatments prevented polypeptide chain elongation on chloroplast ribosomes and thus allowed the polyosomes to remain bound to the thylakoids. Addition of lincomycin, an inhibitor of chain initiation on 70S ribosomes, inhibited the assembly of polysome-thylakoid membrane complex in the light. These results support a model in which initiation of mRNA translation begins in the chloroplast stroma, and the polysome subsequently becomes attached to the thylakoid membrane. Upon natural chain termination, the chloroplast ribosomes are released from the membrane into the stroma.     

Thylakoid-Bound Ascorbate Peroxidase in Spinach Chloroplasts and Photoreduction of Its Primary Oxidation Product Monodehydroascorbate Radicals in Thylakoids

Ascorbate peroxidase, a key enzyme for the scavenging of hydrogenperoxide in chloroplasts, was found in a thylakoid-bound formin spinach chloroplasts at comparable activity to that in thestroma. The activity of peroxidase was detectable in the thylakoidsonly when prepared by an ascorbate-containing medium, and enrichedin the stroma thylakoids. The thylakoid enzyme was not releasedfrom the membranes by either 2 mM EDTA, 1 M KCl, 2 M NaBr or2 M NaSCN, but was solubilized by detergents. Enzymatic propertiesof the thylakoid-bound ascorbate peroxidase were very similarto those of the stromal ascorbate peroxidase. Thylakoid-bound ascorbate peroxidase could scavenge the hydrogenperoxide either added or photoproduced by the thylakoids. Nophotoreduction of hydrogen peroxide was observed, however, inthe thylakoids whose ascorbate peroxidase was inhibited by KCNand thiol reagents or inactivated by the treatment with ascorbate-depletion.The primary oxidation product of ascorbate in a reaction ofascorbate peroxidase, monodehydroascorbate (MDA) radical, wasphotoreduced in the thylakoids, as detected by the quenchingof chlorophyll fluorescence, disappearance of EPR signals ofthe MDA radicals and the MDA radical-induced oxygen evolution.Thus, ascorbate is photoregenerated in the thylakoids from theMDA radicals produced in a reaction of ascorbate peroxidasefor the scavenging of hydrogen peroxide. (Received March 26, 1992; Accepted April 22, 1992)     

Requirement for three membrane-spanning alpha-helices in the post-translational insertion of a thylakoid membrane protein.

The insertion of a protein into a lipid bilayer usually involves a short signal sequence and can occur either during or after translation. A light-harvesting chlorophyll a/b-binding protein (LHCP) is synthesized in the cytoplasm of plant cells as a precursor and is post-translationally imported into chloroplasts where it subsequently inserts into the thylakoid membrane. Only mature LHCP is required for insertion into the thylakoid. To define which sequences of the mature protein are necessary and sufficient for thylakoid integration, fusion and deletion proteins and proteins with internal rearrangements were synthesized and incubated with isolated thylakoids and stroma. No evidence is found for the existence of a short signal sequence within LHCP, and, with the exception of the amino terminus and a short lumenal loop, the entire mature protein with consecutively ordered alpha-helices is required for insertion into thylakoid membranes. The addition of positive charges into stromal but not lumenal segments permits the insertion of mutant LHCPs into isolated thylakoids. Replacement of the LHCP transit peptide with the transit peptide from plastocyanin has no effect on LHCP insertion and does not restore insertion of the lumenal charge addition mutants.     

Full-length plastocyanin precursor is translocated across isolated thylakoid membranes

In higher plants, the chloroplastic protein plastocyanin is synthesized as a transit peptide-containing precursor by cytosolic ribosomes and posttranslationally transported to the thylakoid lumen. En route to the lumen, a plastocyanin precursor is first imported into chloroplasts and then further directed across the thylakoid membrane by a second distinct transport event. A partially processed form of plastocyanin is observed in the stroma during import experiments using intact chloroplasts and has been proposed to be the translocation substrate for the second step (Smeekens, S., Bauerle, C., Hageman, J., Keegstra, K., and Weisbeek, P. (1986) Cell 46, 365-375). To further characterize this second step, we have reconstituted thylakoid transport in a system containing in vitro-synthesized precursor proteins and isolated thylakoid membranes. This system was specific for lumenal proteins since stromal proteins lacking the appropriate targeting information did not accumulate in the thylakoid lumen. Plastocyanin precursor was taken up by isolated thylakoids, proteolytically processed to mature size, and converted to holo form. Translocation was temperature-dependent and was stimulated by millimolar levels of ATP but did not strictly require the addition of stromal factors. We have examined the substrate requirements of thylakoid translocation by testing the ability of different processed forms of plastocyanin to transport in the in vitro system. Interestingly, only the full-length plastocyanin precursor, not the partially processed intermediate form, was competent for transport in this in vitro system.     

Synthesis of the alpha and beta subunits of coupling factor 1 by polysomes from pea chloroplasts

Washed thylakoids of pea chloroplasts, containing tightly bound polysomes, incorporate radioactive amino acids into protein when supplied with soluble factors from Escherichia coli. Polyacrylamide gel electrophoresis with lithium dodecyl sulfate, followed by autoradiography of the labeled products, showed the synthesis of a number of different polypeptides. Two of the most heavily labeled products were in the region expected for the alpha and beta subunits of coupling factor 1, at 57 and 54 kDa. Positive identification of the subunits was made using monospecific antibodies. Furthermore, the same two polypeptides made by soluble polysomes located in the chloroplast stroma were found. While the major proportion of the newly formed alpha and beta subunits made by thylakoid-bound polysomes remained with the thylakoids after protein synthesis occurred, no evidence was found of incorporation into complete, EDTA-extractable coupling factor 1.     

Involvement of a chloroplast homologue of the signal recognition particle receptor protein, FtsY, in protein targeting to thylakoids

We isolated an Arabidopsis thaliana cDNA whose translated product shows sequence similarity to the FtsY, a bacterial homologue of SRP receptor protein. The Arabidopsis FtsY homologue contains a typical chloroplast transit peptide. The in vitro-synthesized 37 kDa FtsY homologue was imported into chloroplasts, and the processed 32 kDa polypeptide bound peripherally on the outer surface of thylakoids. Antibodies raised against the FtsY homologue also reacted with a thylakoid-bound 32 kDa protein. The antibodies inhibited the cpSRP-dependent insertion of the light-harvesting chlorophyll alb-binding protein into thylakoid membranes suggesting that the chloroplast FtsY homologue is involved in the cpSRP-dependent protein targeting to the thylakoid membranes.     

In vitro synthesis and assembly of the peripheral subunits of coupling factor CF1 (alpha and beta) by thylakoid-bound ribosomes

Bispecific antisera were prepared to a mixture of thylakoid membrane polypeptides 4.1 and 4.2. The identity of these polypeptides as the alpha and beta subunits of coupling factor (CF1) was established based on the cross-reactivity of the antisera toward CF1 from peas and by an analysis of the thm-24 mutant of Chlamydomonas which lacks the CF1 ATPase. Photochemical labeling of thylakoid membranes with hydrophobic and hydrophilic fluorescent probes indicated that these polypeptides did not significantly penetrate the membrane bilayer. Immunoprecipitation of the translation products of thylakoid-bound and soluble ribosomes showed the thylakoids to be the major site of synthesis of the polypeptides. Immunoprecipitation of the products of translation of total cellular RNA in a reticulocyte lysate showed no evidence for substantially higher molecular weight precursors. Further analysis of the thylakoid-bound synthesis of alpha and beta revealed that some of the in vitro synthesized polypeptides had been incorporated into the CF0-CF1 complex based on their release from membranes with trypsin and copurification with the CF0-CF1 ATPase.     

A proton gradient is required for the transport of two lumenal oxygen-evolving proteins across the thylakoid membrane.

The 33- and 23-kDa proteins of the photosynthetic oxygen-evolving complex are synthesized in the cytosol as larger precursors and transported into the thylakoid lumen via stromal intermediate forms. We have investigated the energetics of protein transport across the thylakoid membrane using import assays that utilize either intact chloroplasts or isolated thylakoids. We have found that the light-driven import of the 23-kDa protein into isolated thylakoids is almost completely inhibited by electron transport inhibitors or by the ionophore nigericin but not by valinomycin. These compounds have similar effects in chloroplast import assays: precursors of both the 33- and 23-kDa proteins are imported and processed to intermediate forms in the stroma, but transport into the thylakoid lumen is blocked when electron transport is inhibited or nigericin is present. These results indicate that the transport of these proteins across the thylakoid membrane requires a protonmotive force and that the dominant component in this respect is the proton gradient and not the electrical potential.     

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.     

Localization and integration of thylakoid protein translocase subunit cpTatC

Thylakoid membranes have a unique complement of proteins, most of which are nuclear encoded synthesized in the cytosol, imported into the stroma and translocated into thylakoid membranes by specific thylakoid translocases. Known thylakoid translocases contain core multi-spanning, membrane-integrated subunits that are also nuclear-encoded and imported into chloroplasts before being integrated into thylakoid membranes. Thylakoid translocases play a central role in determining the composition of thylakoids, yet the manner by which the core translocase subunits are integrated into the membrane is not known. We used biochemical and genetic approaches to investigate the integration of the core subunit of the chloroplast Tat translocase, cpTatC, into thylakoid membranes. In vitro import assays show that cpTatC correctly localizes to thylakoids if imported into intact chloroplasts, but that it does not integrate into isolated thylakoids. In vitro transit peptide processing and chimeric precursor import experiments suggest that cpTatC possesses a stroma-targeting transit peptide. Import time-course and chase assays confirmed that cpTatC targets to thylakoids via a stromal intermediate, suggesting that it might integrate through one of the known thylakoid translocation pathways. However, chemical inhibitors to the cpSecA-cpSecY and cpTat pathways did not impede cpTatC localization to thylakoids when used in import assays. Analysis of membranes isolated from Arabidopsis thaliana mutants lacking cpSecY or Alb3 showed that neither is necessary for cpTatC membrane integration or assembly into the cpTat receptor complex. These data suggest the existence of another translocase, possibly one dedicated to the integration of chloroplast translocases.     

Synthesis of EF-Tu and distribution of its mRNA between stroma and thylakoids during the cell cycle of Chlamydomonas reinhardii

In Chlamydomonas reinhardii the elongation factor EF-Tu is encoded in the chloroplast DNA. We identified EF-Tu in the electrophoretic product pattern of chloroplast-made proteins and showed that this protein is only synthesized in the first half of the light period in synchronized cells. The newly synthesized EF-Tu contributed little to the almost invariable content of EF-Tu in chloroplasts during the light period of the cell cycle. However, increasing cell volume and the lack of EF-Tu synthesis in the second half of the light period led to a decrease in the concentration of EF-Tu in chloroplasts. At different times in the vegetative cell cycle, the RNA was extracted from whole chloroplasts and from free and thylakoid-bound chloroplast polysomes. The content of mRNA of EF-Tu in chloroplasts and the distribution between stroma and thylakoids were determined. During the light period, the content of the mRNA for EF-Tu varied in parallel to the rate of EF-Tu synthesis. However, in the dark, some mRNA was present even in the absence of EF-Tu synthesis. Most of the mRNA was bound to thylakoids during the whole cell cycle. This suggests that synthesis of EF-Tu is associated with thylakoid membranes.     

Translation of heterologous mRNAs by chloroplast stroma components

In vitro translation of exogenous mRNAs has been difficult to achieve using chloroplast components. An in vitro protein synthesis system is described, based on a pea ( Pisum sativum L, cv. Spring) chloroplast stroma 30000 g supernatant, which was capable of translating polyuridylie acid and MS2 phage RNA into corresponding proteins. The kinetics of label incorporation and fluorograms of unique translation products are presented. The unusual steps which may have contributed to successful translation include the following: the removal of exogenous unlabeled amino acids from the incubation mixture, ultrafiltration of the stromal supernatant and the removal of thylakoid-bound polyribosomes. The system could be further developed to study translational control of gene expression in the chloroplasts.     

Targeting of ricin A chain into pea chloroplasts

A chimaeric gene was constructed encoding the pre-sequence of the 33 kDa oxygen-evolving complex protein from wheat (a thylakoid lumen protein) linked to ricin A chain. The fusion protein is efficiently imported by isolated pea chloroplasts and localised partly in the stroma, with the remainder bound to the stromal surface of the thylakoids. The imported protein is fully processed by both the stromal and thylakoidal processing peptidases, indicating that partial or complete translocation across the thylakoid membrane has taken place.