Membrane proteins synthesized but not processed by isolated maize chloroplasts

One-dimensional maps of proteolytic fragments generated by digestion with Staphylococcus aureus protease in sodium dodecyl sulfate (SDS) were used to identify three polypeptides synthesized by isolated Zea mays chloroplasts. This technique does not depend upon proper incorporation of the newly synthesized polypeptides into a more complex structure for their identification. The only preliminary purification required is electrophoretic separation on SDS-polyacrylamide gels. The pattern of radioactive fragments from labeled proteins which co-migrate with the alpha and beta subunits of chloroplast coupling factor (CF1) corresponds precisely to the pattern of stainable fragments derived from subunits of the purified enzyme. A 34,500-dalton protein is the major membrane-associated product of protein synthesis by isolated maize chloroplasts. From the similarity in the fragments formed by digestion with S. aureus protease, it appears that this radioactive protein is probably a precursor of a 32,000-dalton protein which is a component of the thylakoid. The alpha and beta subunits of CF1 newly synthesized by isolated chloroplasts are not fully extractable by procedures which normally solubilize the enzyme from membranes. The 34,500-dalton protein is not processed to the 32,000-dalton form in any great amount by isolated chloroplasts. A 19,000-dalton fragment of the 32,000-dalton protein is protected from digestion when thylakoids are treated with proteases, while the newly synthesized 34,500-dalton protein is fully susceptible. The isolated chloroplast does not appear to be able to fully integrate these newly made proteins into the membrane structure.     

The chloroplast 32 kDa protein is synthesized on thylakoid-bound ribosomes in Chlamydomonas reinhardtii

A cloned cpDNA fragment containing a portion of the gene for the 32–36 kDa thylakoid protein of Chlamydomonas (polypeptide D-1) was isolated. Hybridization probing of RNA from soluble and membrane fractions of Chlamydomonas showed that the mRNA for D-1 is bound to thylakoid membranes. Run-off translation of thylakoid-bound polysomes (rough thylakoids) with [³⁵S]-methionine yields polypeptide D-1 as the major product. Peptide mapping with S. aureus V-8 protease of D-1 synthesized (1) in vivo, (2) in vitro by rough thylakoids and (3) in the reticulocyte lysate directed by non-polyadenylated RNA showed that D-1 is synthesized as a precursor in the reticulocyte lysate but as the mature polypeptide by rough thylakoids.     

Quantification of mRNA in Chloroplasts of Chlamydomonas reinhardii: Equal Distribution of mRNA for a Soluble and a Membrane Polypeptide in Stroma and Thylakoids

The relative contents of the mRNAs were analyzed for the 32kDa herbicide-binding protein and for the large subunit of ribulose-l,5-bisphosphatecarboxylase in the membrane fraction and in the soluble fractionof chloroplasts from Chlamydomonas reinhardii. The presenceof mRNA for the two proteins in both subchloroplast fractionswas demonstrated by in vitro translation of isolated RNA inthe reticulocyte lysate. The relative amounts of the two mRNAswere measured by hybridizations with cloned chloroplast DNAprobes at two stages of the cell cycle. Both mRNAs were distributedin the same ratio between membrane and soluble fractions, about75% of both mRNAs being in the membrane and 25% in the solublefraction. Therefore, in chloroplasts the accumulation of mRNAson thylakoid membranes does not reflect the final localizationof soluble and membrane proteins. ¹Present address: Department of Biology, Ben Gurion University,Beer-Sheva, Israel. (Received April 28, 1987; Accepted September 29, 1987)     

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.     

The stromal protein large subunit of ribulose-1,5-bisphosphate carboxylase is translated by membrane-bound ribosomes.

Translation of the large subunit of ribulose-1,5-bisphosphate carboxylase (LSU) was investigated by labeling of isolated barley plastids with [35S]-methionine. In both chloroplasts and etioplasts, labeling of LSU was severely impaired if plastid membranes were removed from the reaction mixtures. Removal of membrane-bound polysomes with high salt or puromycin greatly decreased translation of LSU. Pulse-labeled chloroplast membranes were shown to release LSU if chased with unlabeled methionine in the presence of stroma. Immunoprecipitation detected higher amounts of labeled LSU translation intermediates associated with the membrane fraction than in the soluble fraction. We therefore conclude that, in plastids, membrane-bound polysomes are required not only for translation of membrane-intrinsic proteins but also for translation of a soluble protein.     

Import of proteins into chloroplasts. Membrane integration of a thylakoid precursor protein reconstituted in chloroplast lysates

Many of the thylakoid membrane proteins of plant and algal chloroplasts are synthesized in the cytosol as soluble, higher molecular weight precursors. These precursors are post-translationally imported into chloroplasts, incorporated into the thylakoids, and proteolytically processed to mature size. In the present study, the process by which precursors are incorporated into thylakoids was reconstituted in chloroplast lysates using the precursor to the light-harvesting chlorophyll a/b protein (preLHCP) as a model. PreLHCP inserted into thylakoid membranes, but not envelope membranes, if ATP was present in the reaction mixture. Correct integration into the bilayer was verified by previously documented criteria. Integration could also be reconstituted with purified thylakoid membranes if reaction mixtures were supplemented with a soluble extract of chloroplasts. Several other thylakoid precursor proteins in addition to preLHCP, but no stromal precursor proteins, were incorporated into thylakoids under the described assay conditions. These results suggest that the observed in vitro activity represents in vivo events during the biogenesis of thylakoid proteins.     

Insertion of leader peptidase into the thylakoid membrane during synthesis in a chloroplast translation system

The mechanisms of targeting and insertion of chloroplast-encoded thylakoid membrane proteins are poorly understood. In this study, we have used a translation system isolated from chloroplasts to begin to investigate these mechanisms. The bacterial membrane protein leader peptidase (Lep) was used as a model protein because its targeting and insertion mechanisms are well understood for Escherichia coli and for the endoplasmic reticulum. Lep could thus provide insight into the functional homologies between the different membrane systems. Lep was efficiently expressed in the chloroplast translation system, and the protein could be inserted into thylakoid membranes with the same topology as in E. coli cytoplasmic membranes, following the positive-inside rule. Insertion of Lep into the thylakoid membrane was stimulated by the trans-thylakoid proton gradient and was strongly inhibited by azide, suggesting a requirement for SecA activity. Insertion most likely occurred in a cotranslational manner, because insertion could only be observed if thylakoid membranes were present during translation reactions but not when thylakoid membranes were added after translation reactions were terminated. To halt the elongation process at different stages, we translated truncated Lep mRNAs without a stop codon, resulting in the formation of stable ribosome nascent chain complexes. These complexes showed a strong, salt-resistant affinity for the thylakoid membrane, implying a functional interaction of the ribosome with the membrane and supporting a cotranslational insertion mechanism for Lep. Our study supports a functional homology for the insertion of Lep into the thylakoid membrane and the E. coli cytoplasmic membrane.     

Thylakoid membranes: the translational site of chloroplast DNA-regulated thylakoid polypeptides

Stromal ribosomes and those bound to thylakoid membranes were prepared from intact spinach chloroplasts which were purified on Percoll gradients. The products of read-out translation of these ribosomes supplemented with an Escherichia coli extract were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Striking similarity was found between the polypeptides labeled in the read-out translation of the chloroplastic ribosomes and those synthesized in isolated chloroplasts. Among the polypeptides translated on thylakoid-bound ribosomes, apoprotein of chlorophyll-protein complex I, alpha and beta subunits of coupling factor 1, and 32,000-Da membrane polypeptide were identified from their mobility on the polyacrylamide gel. The large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase and other several stromal proteins were translated exclusively from stromal ribosomes. However, when the translation was programmed in cell-free systems from either E. coli, wheat germ, or rabbit reticulocytes by RNAs isolated separately from stroma and thylakoids, no qualitative difference was found between the products from those RNAs. These results suggest that thylakoid-bound ribosomes are the main sites of synthesis of thylakoid proteins and stromal-free ribosomes are that of stromal proteins, and that thylakoids and stroma contain mRNAs for the stromal and the thylakoid proteins, respectively, in a form not functioning in the chloroplasts.     

Optimal conditions for post-translational uptake of proteins by isolated chloroplasts. In vitro synthesis and transport of plastocyanin, ferredoxin-NADP+ oxidoreductase, and fructose-1,6-bisphosphatase

Many polypeptides translated in the cytosol enter the chloroplast where they assemble into macromolecular complexes. The transport of these polypeptides into the plastid can be examined in vitro by mixing isolated chloroplasts with pea poly(A) RNA translation products. Following optimization of both translation in the wheat germ system and the conditions during in vitro uptake, we observe the post-translational transport of over 100 polypeptides; many remain in the soluble phase of the organelle while others integrate into the thylakoid membranes. Most products transported in vitro co-migrate with in vivo products on sodium dodecyl sulfate-polyacrylamide gels. Furthermore, with the improved conditions, we demonstrate the transport of plastocyanin, ferredoxin-NADP+ oxidoreductase, and fructose-1,6-bisphosphatase into isolated plastids. While we have not been able to detect any cell-free translation product that is immunologically related to fructose-1,6-bisphosphatase, both plastocyanin and ferredoxin-NADP+ oxidoreductase are synthesized as precursors in vitro. These precursors are imported into the organelle where they are processed to the size of their mature counterparts. As determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the molecular weight of the precursor to plastocyanin is 15,000 larger than the mature product and the precursor to ferredoxin-NADP+ oxidoreductase is 8,000 larger than the mature product.     

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.     

Detection of a Precursor Polypeptide of the Rapidly-Synthesized 32,000-Dalton Thylakoid Protein in Spinach Chloroplasts

Spinach chloroplast RNA was translated in a wheat germ cell-freesystem in the presence of [³⁵S]methionine or [³H]lysine, andthe products were analyzed by SDS polyacrylamide gel electrophoresisand fluorography. A polypeptide with molecular mass of 2,000-Dalarger than the 32,000-Da thylakoid protein was detected asa major product labeled by [³⁵S]methionine but not by [³H]lysine.Peptide mapping of this polypeptide showed a pattern very closeto that of the 32,000-Da protein synthesized in isolated chloroplasts.A better separation of this polypeptide from the 32,000-Da proteinwas observed in the electrophoresis on polyacrylamide gel includingurea at 8 M. Pulse-labeling of the isolated chloroplasts showedthe occurrence of the larger molecular weight form, which wasconverted to the mature size by a chasing incubation with coldmethionine. These results suggested that the 32,000-Da proteinof spinach is translated primarily as a high molecular weightprecursor in the chloroplasts, as has been reported for otherplant species. (Received March 30, 1985; Accepted April 23, 1985)     

Multiple pathways for protein transport into or across the thylakoid membrane.

Many thylakoid proteins are cytosolically synthesized and have to cross the two chloroplast envelope membranes as well as the thylakoid membrane en route to their functional locations. In order to investigate the localization pathways of these proteins, we over-expressed precursor proteins in Escherichia coli and used them in competition studies. Competition was conducted for import into the chloroplast and for transport into or across isolated thylakoids. We also developed a novel in organello method whereby competition for thylakoid transport occurred within intact chloroplasts. Import of all precursors into chloroplasts was similarly inhibited by saturating concentrations of the precursor to the OE23 protein. In contrast, competition for thylakoid transport revealed three distinct precursor specificity groups. Lumen-resident proteins OE23 and OE17 constitute one group, lumenal proteins plastocyanin and OE33 a second, and the membrane protein LHCP a third. The specificity determined by competition correlates with previously determined protein-specific energy requirements for thylakoid transport. Taken together, these results suggest that thylakoid precursor proteins are imported into chloroplasts on a common import apparatus, whereupon they enter one of several precursor-specific thylakoid transport pathways.     

Ribosomes pause at specific sites during synthesis of membrane-bound chloroplast reaction center protein D1

Photosynthetic reaction center protein D1 contains five membrane-spanning alpha-helices which form binding sites for pheophytin, chlorophyll, carotenoids, quinone, Fe2+, and probably Mn2+. D1 translation intermediates of 15 to 28 kD were detected when isolated chloroplasts were pulse-labeled with [35S]methionine. The D1 translation intermediates were associated with membrane polysomes and can be chased into full length D1. The sites of translation pausing were determined by mapping the distribution of ribosomes on D1 mRNA using toeprint analysis. Clusters of toeprint signals were generated by D1 mRNA associated with membranes but not by D1 mRNA in nonpolysomal fractions of the soluble phase or phenol-extracted mRNA. The distribution of ribosomes on D1 mRNA determined by toeprint analysis was consistent with D1 translation intermediates observed with pulse-labeling. Ribosome pausing may facilitate co-translational binding of co-factors such as chlorophyll to D1 and aid the integration of D1 into thylakoid membranes.     

Evidence for the localization of the nuclear-coded 22-kDa heat-shock protein in a subfraction of thylakoid membranes.

The precursor to the nuclear-coded 22-kDa heat-shock protein of chloroplasts (HSP 22) has been transported into isolated intact chloroplasts from heat-shocked plants. The localization of the mature protein in the chloroplast membrane was investigated. We have shown that the processed HSP 22 of pea was not bound to envelopes and found predominantly in thylakoid membranes. The binding of HSP 22 was stable in the presence of high salt concentrations. Solubilization of thylakoid membranes with Triton X-100 and phase partitioning with Triton X-114 indicate an intrinsic localization of HSP 22 or, alternatively, a non-covalent association with integral membrane protein(s). After fractionation into grana and stroma lamellae, HSP 22 was found mostly in the grana-membrane subfraction.     

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.     

Cytosolic events involved in chloroplast protein targeting

Chloroplasts are unique organelles that are responsible for photosynthesis. Although chloroplasts contain their own genome, the majority of chloroplast proteins are encoded by the nuclear genome. These proteins are transported to the chloroplasts after translation in the cytosol. Chloroplasts contain three membrane systems (outer/inner envelope and thylakoid membranes) that subdivide the interior into three soluble compartments known as the intermembrane space, stroma, and thylakoid lumen. Several targeting mechanisms are required to deliver proteins to the correct chloroplast membrane or soluble compartment. These mechanisms have been extensively studied using purified chloroplasts in vitro. Prior to targeting these proteins to the various compartments of the chloroplast, they must be correctly sorted in the cytosol. To date, it is not clear how these proteins are sorted in the cytosol and then targeted to the chloroplasts. Recently, the cytosolic carrier protein AKR2 and its associated cofactor Hsp17.8 for outer envelope membrane proteins of chloroplasts were identified. Additionally, a mechanism for controlling unimported plastid precursors in the cytosol has been discovered. This review will mainly focus on recent findings concerning the possible cytosolic events that occur prior to protein targeting to the chloroplasts. This article is part of a Special Issue entitled: Protein Import and Quality Control in Mitochondria and Plastids.     

Assembly of Newly Imported Oxygen-Evolving Complex Subunits in Isolated Chloroplasts: Sites of Assembly and Mechanism of Binding

We have examined the assembly of the nuclear-encoded subunits of the oxygen-evolving complex (OEC) after their import into isolated intact chloroplasts. We showed that all three subunits examined (OE33, OE23, and OE17) partition between the thylakoid lumen and a site on the inner surface of the thylakoid membrane after import in a homologous system (e.g., pea or spinach subunits into pea or spinach chloroplasts, respectively). Although some interspecies protein import experiments resulted in OEC subunit binding, maize OE17 did not bind thylakoid membranes in chloroplasts isolated from peas. Newly imported OE33 and OE23 were washed from the membranes at the same concentrations of urea and NaCl as the native, indigenous proteins; this observation suggests that the former subunits are bound productively within the OEC. Inhibition of neither chloroplast protein synthesis nor light- or ATP-dependent energization of the thylakoid membrane significantly affected these assembly reactions, and we present evidence suggesting that incoming subunits actively displace those already bound to the thylakoid membrane. Transport of OE33 took place primarily in the stromal-exposed membranes and proceeded through a protease-sensitive, mature intermediate. Initial binding of OE33 to the thylakoid membrane occurred primarily in the stromal-exposed membranes, from where it migrated with measurable kinetics to the granal region. In contrast, OE23 assembly occurred in the granal membrane regions. This information is incorporated into a model of the stepwise assembly of oxygen-evolving photosystem II.     

Transport of methotrexate in Chinese hamster ovary cells: a mutant defective in methotrexate uptake and cell binding

A regulatory role for cytoplasmically derived proteins in chloroplast translation in organello was examined by analyzing protein synthesis in plastids isolated from cells of Euglena gracilis which had been treated with cycloheximide (CHI). Incorporation of [35S]methionine by chloroplasts from CHI-inhibited Euglena was reduced approximately 40 and 90% by exposure of the cells to the antibiotic for 2 and 4 h, respectively. The chloroplast translation products were then analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography. The synthesis of polypeptides in the soluble compartment of the plastid was substantially diminished by as little as 15 min of CHI pretreatment. No qualitative alterations of the polypeptide pattern were detected. Qualitative changes were seen in the thylakoid fraction, however. Comparison of the stainable polypeptides and fluorographs of thylakoid membranes from CHI-treated cells with those of controls showed several instances in which the more slowly migrating member of a doublet accumulated with a concomitant depletion of a more rapidly migrating component. A pair of polypeptides at 28 and 30 kDa, which we believe are the Euglena homologs of the photogene product and its precursor, respectively, are representative of this phenomenon. Additionally, thylakoids from cells pretreated with CHI sometimes synthesized novel polypeptides larger than 65 kDa. Finally, when intact chloroplasts from CHI-inhibited Euglena were incubated with a postchloroplast supernatant from normal cells, there was a partial reversion of the anomalies seen in the fluorographs. These data are interpreted to indicate the cytoplasmic origin of one or more proteins whose function is to process chloroplast translation products.