Free and membrane-bound chloroplast polyribosomes Chlamydomonas reinhardtii

Exclusion of plastid nucleoids and ribosomes from stromules in tobacco and Arabidopsis

Stromules are stroma-filled tubules that extend from the surface of plastids and allow the transfer of proteins as large as 550 kDa between interconnected plastids. The aim of the present study was to determine if plastid DNA or plastid ribosomes are able to enter stromules, potentially permitting the transfer of genetic information between plastids. Plastid DNA and ribosomes were marked with green fluorescent protein (GFP) fusions to LacI, the lac repressor, which binds to lacO-related sequences in plastid DNA, and to plastid ribosomal proteins Rpl1 and Rps2, respectively. Fluorescence from GFP-LacI co-localised with plastid DNA in nucleoids in all tissues of transgenic tobacco (Nicotiana tabacum L.) examined and there was no indication of its presence in stromules, not even in hypocotyl epidermal cells, which contain abundant stromules. Fluorescence from Rpl1-GFP and Rps2-GFP was also observed in a punctate pattern in chloroplasts of tobacco and Arabidopsis [Arabidopsis thaliana (L.) Heynh.], and fluorescent stromules were not detected. Rpl1-GFP was shown to assemble into ribosomes and was co-localised with plastid DNA. In contrast, in hypocotyl epidermal cells of dark-grown Arabidopsis seedlings, fluorescence from Rpl1-GFP was more evenly distributed in plastids and was observed in stromules on a total of only four plastids (<0.02% of the plastids observed). These observations indicate that plastid DNA and plastid ribosomes do not routinely move into stromules in tobacco and Arabidopsis, and suggest that transfer of genetic information by this route is likely to be a very rare event, if it occurs at all.

Reconstruction of metabolic pathways, protein expression, and homeostasis machineries across maize bundle sheath and mesophyll chloroplasts: large-scale quantitative proteomics using the first maize genome assembly

Chloroplasts in differentiated bundle sheath (BS) and mesophyll (M) cells of maize (Zea mays) leaves are specialized to accommodate C(4) photosynthesis. This study provides a reconstruction of how metabolic pathways, protein expression, and homeostasis functions are quantitatively distributed across BS and M chloroplasts. This yielded new insights into cellular specialization. The experimental analysis was based on high-accuracy mass spectrometry, protein quantification by spectral counting, and the first maize genome assembly. A bioinformatics workflow was developed to deal with gene models, protein families, and gene duplications related to the polyploidy of maize; this avoided overidentification of proteins and resulted in more accurate protein quantification. A total of 1,105 proteins were assigned as potential chloroplast proteins, annotated for function, and quantified. Nearly complete coverage of primary carbon, starch, and tetrapyrole metabolism, as well as excellent coverage for fatty acid synthesis, isoprenoid, sulfur, nitrogen, and amino acid metabolism, was obtained. This showed, for example, quantitative and qualitative cell type-specific specialization in starch biosynthesis, arginine synthesis, nitrogen assimilation, and initial steps in sulfur assimilation. An extensive overview of BS and M chloroplast protein expression and homeostasis machineries (more than 200 proteins) demonstrated qualitative and quantitative differences between M and BS chloroplasts and BS-enhanced levels of the specialized chaperones ClpB3 and HSP90 that suggest active remodeling of the BS proteome. The reconstructed pathways are presented as detailed flow diagrams including annotation, relative protein abundance, and cell-specific expression pattern. Protein annotation and identification data, and projection of matched peptides on the protein models, are available online through the Plant Proteome Database.

Photosystem II assembly and repair are differentially localized in Chlamydomonas

Many proteins of the photosynthesis complexes are encoded by the genome of the chloroplast and synthesized by bacterium-like ribosomes within this organelle. To determine where proteins are synthesized for the de novo assembly and repair of photosystem II (PSII) in the chloroplast of Chlamydomonas reinhardtii, we used fluorescence in situ hybridization, immunofluorescence staining, and confocal microscopy. These locations were defined as having colocalized chloroplast mRNAs encoding PSII subunits and proteins of the chloroplast translation machinery specifically under conditions of PSII subunit synthesis. The results revealed that the synthesis of the D1 subunit for the repair of photodamaged PSII complexes occurs in regions of the chloroplast with thylakoids, consistent with the current model. However, for de novo PSII assembly, PSII subunit synthesis was detected in discrete regions near the pyrenoid, termed T zones (for translation zones). In two PSII assembly mutants, unassembled D1 subunits and incompletely assembled PSII complexes localized around the pyrenoid, where we propose that they mark an intermediate compartment of PSII assembly. These results reveal a novel chloroplast compartment that houses de novo PSII biogenesis and the regulated transport of newly assembled PSII complexes to thylakoid membranes throughout the chloroplast.

Interactions of ribosome nascent chain complexes of the chloroplast-encoded D1 thylakoid membrane protein with cpSRP54

The mechanisms of targeting, insertion and assembly of the chloroplast-encoded thylakoid membrane proteins are unknown. In this study, we investigated these mechanisms for the chloroplast-encoded polytopic D1 thylakoid membrane protein, using a homologous translation system isolated from tobacco chloroplasts. Truncated forms of the psbA gene were translated and stable ribosome nascent chain complexes were purified. To probe the interactions with the soluble components of the targeting machinery, we used UV-activatable cross-linkers incorporated at specific positions in the nascent chains, as well as conventional sulfhydryl cross-linkers. With both cross-linking approaches, the D1 ribosome nascent chain was photocross-linked to cpSRP54. cpSRP54 was shown to interact only when the D1 nascent chain was still attached to the ribosome. The interaction was strongly dependent on the length of the nascent chain that emerged from the ribosome, as well as the cross-link position. No interactions with soluble SecA or cpSRP43 were found. These results imply a role for cpSRP54 in D1 biogenesis.

A SecY homologue is required for the elaboration of the chloroplast thylakoid membrane and for normal chloroplast gene expression

Results of in vitro and genetic studies have provided evidence for four pathways by which proteins are targeted to the chloroplast thylakoid membrane. Although these pathways are initially engaged by distinct substrates and involve some distinct components, an unresolved issue has been whether multiple pathways converge on a common translocation pore in the membrane. A homologue of eubacterial SecY called cpSecY is localized to the thylakoid membrane. Since SecY is a component of a protein-translocating pore in bacteria, cpSecY likely plays an analogous role. To explore the role of cpSecY, we obtained maize mutants with transposon insertions in the corresponding gene. Null cpSecY mutants exhibit a severe loss of thylakoid membrane, differing in this regard from mutants lacking cpSecA. Therefore, cpSecY function is not limited to a translocation step downstream of cpSecA. The phenotype of cpSecY mutants is also much more pleiotropic than that of double mutants in which both the cpSecA- and DeltapH-dependent thylakoid-targeting pathways are disrupted. Therefore, cpSecY function is likely to extend beyond any role it might play in these targeting pathways. CpSecY mutants also exhibit a defect in chloroplast translation, revealing a link between chloroplast membrane biogenesis and chloroplast gene expression.

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.

Light-regulated translation of chloroplast proteins. I. Transcripts of psaA-psaB, psbA, and rbcL are associated with polysomes in dark-grown and illuminated barley seedlings

We have previously observed (Klein, R. R., and J. E. Mullet, 1986, J. Biol. Chem. 261:11138-11145) that translation of two 65-70-kD chlorophyll a-apoproteins of Photosystem I (gene products of psaA and psaB) and a 32-kD quinone-binding protein of Photosystem II (gene product of psbA) was not detected in plastids of dark-grown barley seedlings even though transcripts for these proteins were present. In the present study it was found that nearly all of the psaA-psaB transcripts in plastids of dark-grown plants were associated with membrane-bound polysomes. Membrane-associated polysomes from plastids of dark-grown plants synthesized the 65-70-kD chlorophyll a-apoproteins at low levels when added to a homologous in vitro translation extract capable of translation elongation. However, when etioplast membranes were disrupted with detergent, in vitro synthesis of the 65-70-kD chlorophyll a-apoproteins increased to levels observed with polysomes of plastids from illuminated plants. These results suggest that synthesis of the chlorophyll a-apoproteins of Photosystem I is arrested on membrane-bound polysomes at the level of polypeptide chain elongation. In addition to the selective activation of chlorophyll a-apoprotein translation, illumination also caused an increase in chloroplast polysomes (membrane-associated and stromal) and induced a recruitment of psbA and rbcL transcripts into chloroplast polysomes. These results indicate that in conjunction with the selective activation of chlorophyll a-apoprotein elongation, illumination also caused a general stimulation of chloroplast translation initiation.

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.

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.

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.

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.

Isolation and characterization of polysomes from thylakoid membranes of Chlamydomonas reinhardii

Chloroplast polysomes that were originally bound to thylakoid membranes were isolated from the cell wall mutant CW-15 from Chlamydomonas reinhardii. Polysomes were isolated from synchronously grown cells harvested in the middle of the third light period, when the ratio of chloroplast to cytoplasmic polysomes was maximal. Thylakoid membranes were isolated from a chloroplast fraction and polysomes were released by Triton X-100. Analyses of subunits on sucrose gradients showed that the polysomes consisted predominantly of the 70 S-type ribosomes. The detached polysomes as well as polysomes still bound to the thylakoid membrane were active in in vitro protein synthesis when supplemented with Escherichia coli-soluble factors. The in vitro activity was inhibited by chloramphenicol and aurintricarboxylic acid, but not by cycloheximide.

Release of ribosomes from thylakoids and endoplasmic reticulum with trypsin

Release by trypsin of chloroplast ribosomes from rough thylakoids of Chlamydomonas reinhardtii was compared with release by trypsin of ribosomes from endoplasmic reticulum of rat liver. Rough thylakoids could be stripped of ribosomes with trypsin. Ribosomes were released as a mixture of polysomes, monosomes, and subunits. Chymotrypsin was much less effective than trypsin. Released ribosomes behaved like intact particles on zone velocity centrifugation, but showed extensive modification of their polypeptides. Stripped thylakoids sedimented as membranes, but also showed extensive modification of their polypeptides. Some ribosomes could be released in polysomes from rough endoplasmic reticulum by trypsin, provided the incubation mixture contained rat liver extract as a source of RNAase inhibitor. In its absence, ribosomes were released predominantly as monosomes, as reported by others. The rat liver extract inhibited release of polysomes from rough thylakoids by trypsin. Thus, the difference in form in which ribosomes are released from thylakoids, and endoplasmic reticulum by trypsin may be due to the high RNAase content of the latter.

Sub-thylakoid fractions containing ribosomes

A sub-membrane fraction which contains a large portion of any thylakoid-bound ribosomes can be obtained when thylakoids are treated with the detergents Nonidet P-40, or Triton X-100. These 'pseudopolysome' fractions contain 50% of thylakoid-bound ribosomes, but less than 0.5% of thylakoid chlorophyll. Triton and Nonidet psuedopolysomes contain about 10%, and 3% of thylakoid protein, respectively. Pseudopolysomes, prepared from thylakoids with low levels of ribosomes, contain about the same proportion of thylakoid protein but proportionately less ribosomes. Pseudopolysomes contain thylakoid polypeptides in addition to chlorophyll, but lack a major membrane polypeptide of Mr 50 000. Pseudopolysome chlorophyll, and RNA band at the same buoyant density. However, they band at different densities after pseudopolysomes are treated with trypsin (a procedure which strips thylakoids of ribosomes). Pseudopolysome fractions from thylakoids with low levels of ribosomes have a lower density than the corresponding fractions from thylakoids with high levels of ribosomes. Ribosomes are released from thylakoids, and pseudopolysomes by the same treatments. Subunits are released with KCl and puromycin. Polysomes are released with trypsin. It was concluded the pseudopolysomes consist of ribosomes and a membrane fragment containing the sites to which ribosomes are bound.

Sedimentation behavior of chloroplast ribosomes from Chlamydomonas reinhardtii

The identity of peaks generated by chloroplast ribosomes of Chlamydomonas reinhardtii were determined by zone velocity sedimentation on sucrose density gradients, and analysis of distribution of ribosomal RNAs in the gradients. The sedimentagion coefficient of the principal peak was 66-70 S (usually 69 S), in good agreement with previously reported values for chloroplast ribosomes of C. reinhardtii, and other organisms. The fast sedimenting side of the 69 S peak contained an excess of chloroplast large subunit. When ribosome dissociation was prevented by sedimentation at low velocity, by aldehyde fixation, or by the presence of nascent polypeptide chains, the principal peak had a sedimentation coefficient of about 75 S. Thus the 69 S peak was an artifact caused by dissociation during centrifugation. Peaks that contained chloroplast ribosomal RNAs were also observed at '60 S' and '45 S' when chloroplast ribosomes were centrifuged unfixed at high velocity. The amounts of '60 S' and '45 S' components were decreased by centrifugation at low speed, or fixation, but sedimentation coefficients remained unchanged. The '60 S', and '45 S' components were identified as large, and small subunits of chloroplast ribosomes, respectively. The artifacts produced by centrifugation of chloroplast ribosomes, are similar to the artifacts produced by centrifuging ribosomes of Escherichia coli. Similar explanations appear to apply to both. We concluded that the 69 S chloroplast ribosome peak occurs because of dissociation of 'tight' couples, and incomplete separation of subunits. Subunit peaks (60 S and 45 S) arise from free subunits, and/or from dissociation of 'loose' couples.

The distribution of nascent polypeptide chains among intact polyribosomes from Chlamydomonas reinhardi

A model of polyribosome function based on tape theory has been applied to the analysis of intact polyribosomes from Chlamydomonas reinhardi. The distribution of nascent polypeptide chains found on polyribosomes does not conform to the expected pattern in which small polypeptides are synthesized on small polyribosomes and large polypeptides on correspondingly large polyribosomes. This discrepancy was revealed in the analysis of specific activity of polyribosomes (radioactivity in nascent chains per ribosome) versus polyribosome size at labeling saturation. It was found that the specific activity of small polyribosomes was higher than predicted and that of large polyribosomes was lower. This finding was validated by measuring the sizes of nascent chains from various polyribosome size classes by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. The presence of large polypeptides on small polyribosomes could be partially accounted for by the synthesis of polypeptides on chloroplast (chloramphenicol-sensitive) polyribosomes. A maximum peptide interval time of 10 s was estimated from the labeling kinetics of the nascent chains of mid-sized (cytoplasmic) polyribosomes. This rate of translation is comparable to that reported in other eucaryotic cells.