Chaperone-assisted Post-translational Transport of Plastidic Type I Signal Peptidase 1

Type I signal peptidase (SPase I) is an integral membrane Ser/Lys protease with one or two transmembrane domains (TMDs), cleaving transport signals off translocated precursor proteins. The catalytic domain of SPase I folds to form a hydrophobic surface and inserts into the lipid bilayers at the trans-side of the membrane. In bacteria, SPase I is targeted co-translationally, and the catalytic domain remains unfolded until it reaches the periplasm. By contrast, SPases I in eukaryotes are targeted post-translationally, requiring an alternative strategy to prevent premature folding. Here we demonstrate that two distinct stromal components are involved in post-translational transport of plastidic SPase I 1 (Plsp1) from Arabidopsis thaliana, which contains a single TMD. During import into isolated chloroplasts, Plsp1 was targeted to the membrane via a soluble intermediate in an ATP hydrolysis-dependent manner. Insertion of Plsp1 into isolated chloroplast membranes, by contrast, was found to occur by two distinct mechanisms. The first mechanism requires ATP hydrolysis and the protein conducting channel cpSecY1 and was strongly enhanced by exogenously added cpSecA1. The second mechanism was independent of nucleoside triphosphates and proteinaceous components but with a high frequency of mis-orientation. This unassisted insertion was inhibited by urea and stroma extract. During import-chase assays using intact chloroplasts, Plsp1 was incorporated into a soluble 700-kDa complex that co-migrated with the Cpn60 complex before inserting into the membrane. The TMD within Plsp1 was required for the cpSecA1-dependent insertion but was dispensable for association with the 700-kDa complex and also for unassisted membrane insertion. These results indicate cooperation of Cpn60 and cpSecA1 for proper membrane insertion of Plsp1 by cpSecY1.     

Identification of a Role for an Azide-Sensitive Factor in the Thylakoid Transport of the 17-Kilodalton Subunit of the Photosynthetic Oxygen-Evolving Complex

We have examined the transport of the precursor of the 17-kD subunit of the photosynthetic O₂-evolving complex (OE17) in intact chloroplasts in the presence of inhibitors that block two protein-translocation pathways in the thylakoid membrane. This precursor uses the transmembrane pH gradient-dependent pathway into the thylakoid lumen, and its transport across the thylakoid membrane is thought to be independent of ATP and the chloroplast SecA homolog, cpSecA. We unexpectedly found that azide, widely considered to be an inhibitor of cpSecA, had a profound effect on the targeting of the photosynthetic OE17 to the thylakoid lumen. By itself, azide caused a significant fraction of mature OE17 to accumulate in the stroma of intact chloroplasts. When added in conjunction with the protonophore nigericin, azide caused the maturation of a fraction of the stromal intermediate form of OE17, and this mature protein was found only in the stroma. Our data suggest that OE17 may use the sec-dependent pathway, especially when the transmembrane pH gradient-dependent pathway is inhibited. Under certain conditions, OE17 may be inserted across the thylakoid membrane far enough to allow removal of the transit peptide, but then may slip back out of the translocation machinery into the stromal compartment.     

The role of the transmembrane domain in determining the targeting of membrane proteins to either the inner envelope or thylakoid membrane

Chloroplastic membrane proteins can be targeted to any of three distinct membrane systems, i.e., the outer envelope membrane (OEM), inner envelope membrane (IEM), and thylakoid membrane. This complex structure of chloroplasts adds significantly to the challenge of studying protein targeting to various membrane sub-compartments within a chloroplast. In this investigation, we examined the role played by the transmembrane domain (TMD) in directing membrane proteins to either the IEM or thylakoid membrane. Using the IEM protein, Arc6 (Accumulation and Replication of Chloroplasts 6), we exchanged the stop-transfer TMD of Arc6 with various TMDs derived from different IEM and thylakoid membrane proteins and monitored the subcellular localization of these Arc6-hybrid proteins. We showed that when the Arc6 TMD was replaced with a TMD derived from various thylakoid membrane proteins, these Arc6(thylTMD) hybrid proteins could be directed to the thylakoid membrane rather than to the IEM. Conversely, when the TMD of the thylakoid membrane proteins, STN8 (State Transition protein kinase 8) or Plsp1 (Plastidic type I signal peptidase 1), was replaced with the stop-transfer TMD of Arc6, STN8 and Plsp1 were halted at the IEM. From our investigation, we conclude that the TMD plays a critical role in targeting integral membrane proteins to either the IEM or thylakoid membrane.     

Plastidic type I signal peptidase 1 is a redox‐dependent thylakoidal processing peptidase

Thylakoids are the photosynthetic membranes in chloroplasts and cyanobacteria. The aqueous phase inside the thylakoid known as the thylakoid lumen plays an essential role in the photosynthetic electron transport. The presence and significance of thiol‐disulfide exchange in this compartment have been recognized but remain poorly understood. All proteins found free in the thylakoid lumen and some proteins associated to the thylakoid membrane require an N‐terminal targeting signal, which is removed in the lumen by a membrane‐bound serine protease called thylakoidal processing peptidase (TPP). TPP is homologous to Escherichia coli type I signal peptidase (SPI) called LepB. Genetic data indicate that plastidic SPI 1 (Plsp1) is the main TPP in Arabidopsis thaliana (Arabidopsis) although biochemical evidence had been lacking. Here we demonstrate catalytic activity of bacterially produced Arabidopsis Plsp1. Recombinant Plsp1 showed processing activity against various TPP substrates at a level comparable to that of LepB. Plsp1 and LepB were also similar in the pH optima, sensitivity to arylomycin variants and a preference for the residue at ?3 to the cleavage site within a substrate. Plsp1 orthologs found in angiosperms contain two unique Cys residues located in the lumen. Results of processing assays suggested that these residues were redox active and formation of a disulfide bond between them was necessary for the activity of recombinant Arabidopsis Plsp1. Furthermore, Plsp1 in Arabidopsis and pea thylakoids migrated faster under non‐reducing conditions than under reducing conditions on SDS‐PAGE. These results underpin the notion that Plsp1 is a redox‐dependent signal peptidase in the thylakoid lumen.     

Mechanisms of protein import into thylakoids of chloroplasts

The thylakoid membrane of chloroplasts contains the major photosynthetic complexes, which consist of several either nuclear or chloroplast encoded subunits. The biogenesis of these thylakoid membrane complexes requires coordinated transport and subsequent assembly of the subunits into functional complexes. Nuclear-encoded thylakoid proteins are first imported into the chloroplast and then directed to the thylakoid using different sorting mechanisms. The cpSec pathway and the cpTat pathway are mainly involved in the transport of lumenal proteins, whereas the spontaneous pathway and the cpSRP pathway are used for the insertion of integral membrane proteins into the thylakoid membrane. While cpSec-, cpTat- and cpSRP-mediated targeting can be classified as 'assisted' mechanisms involving numerous components, 'unassisted' spontaneous insertion does not require additional targeting factors. However, even the assisted pathways differ fundamentally with respect to stromal targeting factors, the composition of the translocase and energy requirements.     

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.     

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 ΔpH-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.     

Chloroplast Oxa1p homolog albino3 is required for post-translational integration of the light harvesting chlorophyll-binding protein into thylakoid membranes

Multiple sorting pathways operate in chloroplasts to localize proteins to the thylakoid membrane. The signal recognition particle (SRP) pathway in chloroplasts employs the function of a signal recognition particle (cpSRP) to target light harvesting chlorophyll-binding protein (LHCP) to the thylakoid membrane. In assays that reconstitute stroma-dependent LHCP integration in vitro, the stroma is replaceable by the addition of GTP, cpSRP, and an SRP receptor homolog, cpFtsY. Still lacking is an understanding of events that take place at the thylakoid membrane including the identification of membrane proteins that may function at the level of cpFtsY binding or LHCP integration. The identification of Oxa1p in mitochondria, an inner membrane translocase component homologous to predicted proteins in bacteria and to the albino3 (ALB3) protein in thylakoids, led us to investigate the potential role of ALB3 in LHCP integration. Antibody raised against a 50-amino acid region of ALB3 (ALB3-50aa) identified a single 45-kDa thylakoid protein. Treatment of thylakoids with antibody to ALB3-50aa inhibited LHCP integration, whereas the same antibody treatment performed in the presence of antigen reversed the inhibition. In contrast, transport by the thylakoid Sec or Delta pH pathways was unaffected. These data support a model whereby a distinct translocase containing ALB3 is used to integrate LHCP into thylakoid membranes.     

Multiple fates of non‐mature lumenal proteins in thylakoids

Most proteins found in the thylakoid lumen are synthesized in the cytosol with an N–terminal extension consisting of transient signals for chloroplast import and thylakoid transfer in tandem. The thylakoid‐transfer signal is required for protein sorting from the stroma to thylakoids, mainly via the cpSEC or cpTAT pathway, and is removed by the thylakoidal processing peptidase in the lumen. An Arabidopsis mutant lacking one of the thylakoidal processing peptidase homologs, Plsp1, contains plastids with anomalous thylakoids and is seedling‐lethal. Furthermore, the mutant plastids accumulate two cpSEC substrates (PsbO and PetE) and one cpTAT substrate (PsbP) as intermediate forms. These properties of plsp1‐null plastids suggest that complete maturation of lumenal proteins is a critical step for proper thylakoid assembly. Here we tested the effects of inhibition of thylakoid‐transfer signal removal on protein targeting and accumulation by examining the localization of non‐mature lumenal proteins in the Arabidopsis plsp1‐null mutant and performing a protein import assay using pea chloroplasts. In plsp1‐null plastids, the two cpSEC substrates were shown to be tightly associated with the membrane, while non‐mature PsbP was found in the stroma. The import assay revealed that inhibition of thylakoid‐transfer signal removal did not disrupt cpSEC‐ and cpTAT‐dependent translocation, but prevented release of proteins from the membrane. Interestingly, non‐mature PetE2 was quickly degraded under light, and unprocessed PsbO1 and PsbP1 were found in a 440‐kDa complex and as a monomer, respectively. These results indicate that the cpTAT pathway may be disrupted in the plsp1‐null mutant, and that there are multiple mechanisms to control unprocessed lumenal proteins in thylakoids.     

The transit peptide of a chloroplast thylakoid membrane protein is functionally equivalent to a stromal-targeting sequence.

The role of transit peptides in intraorganellar targeting has been studied for a chlorophyll a/b binding (CAB) polypeptide of photosystem II (PSII) and the small subunit of ribulose-1,5-bisphosphate carboxylase (RBCS) from Pisum sativum (pea). These studies have involved in vitro import of fusion proteins into isolated pea chloroplasts. Fusion of the CAB transit peptide to RBCS mediates import to the stroma, as evidenced by assembly of RBCS with chloroplast-synthesized large subunit (RBCL) to form holoenzyme. Similarly, fusion of the RBCS transit peptide to the mature CAB polypeptide mediates import and results in integration of the processed CAB protein into the thylakoid membrane. Correct integration was indicated by association with PSII and assembly with chlorophyll to form the light-harvesting chlorophyll a/b protein complex (LHCII). We interpret these results as evidence that the CAB transit peptide is functionally equivalent to a stromal-targeting sequence and that intraorganellar sorting of the CAB protein must be determined by sequences residing within the mature protein. Our results and those of others suggest that import and integration of CAB polypeptides into the thylakoid proceeds via the stroma.     

Diatom fucoxanthin chlorophyll a/c-binding protein (FCP) and land plant light-harvesting proteins use a similar pathway for thylakoid membrane Insertion

The light-harvesting proteins in plastids of different lineages including algae and land plants represent a superfamily of chlorophyll-binding proteins that seem to be phylogenetically related, although some of the light-harvesting complex (LHC) proteins bind different carotenoids. LHCs can be divided into chlorophyll a/b-binding proteins found in green algae, euglenoids, and higher plants and into chlorophyll a/c-binding proteins of various algal taxa. LHC proteins from diatoms are named fucoxanthin-chlorophyll a/c-binding proteins (FCP). In contrast to chlorophyll a/b-binding proteins, there is no information so far about the way FCPs integrate into thylakoid membranes. The diatom FCP preproteins have a bipartite presequence that is necessary to enable transport into the four membrane-bound diatom plastids, but similar to chlorophyll a/b-binding proteins there is apparently no presequence present for targeting to the thylakoid membrane. By establishing an in vitro import assay for diatom thylakoids, we demonstrated that thylakoid integration of diatom FCP depends on the presence of stromal factors and GTP. This indicates that a pathway involving signal recognition particles (SRP) is involved in membrane integration just as shown for LHCs in higher plants. We also demonstrate integration of diatom FCP into thylakoids of higher plants and vice versa SRP-dependent targeting of LHCs from pea and Arabidopsis into diatom thylakoids. The similar SRP-dependent modes of thylakoid integration of land plant LHCs and FCPs support recent analyses indicating a common origin of chlorophyll a/b- and a/c-binding proteins.     

The 20 kDa apoprotein of the CP24 complex of photosystem II: An alternative model to study import and intra-organellar routing of nuclear-encoded thylakoid proteins

The 20 kDa polypeptide, the apoprotein of the chlorophyll a/b antenna complex CP24 associated with photosystem II, is a remote relative of light-harvesting complex (LHC) apoproteins and thus a member of the extended cab gene family. LHC apoproteins are poly-topic integral components of the thylakoid membrane with probably three transmembrane segments which originate in nuclear genes and are made in the cytosol as precursors. They possess exclusively stroma-targeting transit peptides for import into the organelle and integrate into the thylakoid membrane via uncleaved hydrophobic domains of the mature protein. The CP24 apoprotein displays intriguing structural differences to LHC apoproteins with a potential impact on the routing and targeting processes during biogenesis. In particular, it lacks a pronounced second hydrophobic segment in the mature polypeptide chain found in LHCPs, and carries a transit peptide that is reminiscent of thylakoid-targeting transit peptides. We have used in organello assays with isolated intact chloroplasts and the authentic precursor of the 20 kDa apoprotein from spinach, or appropriate chimaeric polypeptides consisting of a transit peptide and the mature part of various nuclear-encoded thylakoid proteins of known location and targeting epitopes, in order to resolve the characteristics of its targeting properties, as well as to determine the contribution of the individual parts of the precursor molecule to its import and subsequent intra-organellar routing. Our experiments demonstrate that the transit peptide of the CP24 apoprotein is required only for the import of the protein into the organelle. All subsequent steps, such as the integration of the protein into the thylakoid membrane, binding of chlorophyll, assembly into the CP24 complex and migration to the grana lamellae, still take place if the authentic transit peptide is replaced by a targeting signal of a nuclear-encoded stromal protein.     

The Significance of Protein Maturation by Plastidic Type I Signal Peptidase 1 for Thylakoid Development in Arabidopsis Chloroplasts

Thylakoids are the chloroplast internal membrane systems that house light-harvesting and electron transport reactions. Despite the important functions and well-studied constituents of thylakoids, the molecular mechanism of their development remains largely elusive. A recent genetic study has demonstrated that plastidic type I signal peptidase 1 (Plsp1) is vital for proper thylakoid development in Arabidopsis (Arabidopsis thaliana) chloroplasts. Plsp1 was also shown to be necessary for processing of an envelope protein, Toc75, and a thylakoid lumenal protein, OE33; however, the relevance of the protein maturation in both of the two distinct subcompartments for proper chloroplast development remained unknown. Here, we conducted an extensive analysis of the plsp1-null mutant to address the significance of lumenal protein maturation in thylakoid development. Plastids that lack Plsp1 were found to accumulate vesicles of variable sizes in the stroma. Analyses of the mutant plastids revealed that the lack of Plsp1 causes a reduction in accumulation of thylakoid proteins and that Plsp1 is involved in maturation of two additional lumenal proteins, OE23 and plastocyanin. Further immunoblotting and electron microscopy immunolocalization studies showed that OE33 associates with the stromal vesicles of the mutant plastids. Finally, we used a genetic complementation system to demonstrate that accumulation of improperly processed forms of Toc75 in the plastid envelope does not disrupt normal plant development. These results suggest that proper maturation of lumenal proteins may be a key process for correct assembly of thylakoids.Capture of light energy and subsequent electron transport reactions are key steps in photosynthesis. In eukaryotic cells, these reactions occur in thylakoids, the internal membrane systems of chloroplasts. Thylakoid constituents, i.e. membrane lipids, photosynthetic pigments, and various proteins, have been well defined (Schröder and Kieselbach, 2003; Peltier et al., 2004; Benning and Ohta, 2005; DellaPenna and Pogson, 2006; Masuda and Fujita, 2008), and genetic disruptions of their biosynthesis result in a severe reduction of thylakoid development (e.g. Dörmann et al., 1995; Jarvis et al., 1995; Hsieh and Goodman, 2005). Thylakoids depend for their lipid supply on the envelope membranes (Dörmann and Benning, 2002). Early cytological studies suggested that thylakoids derive from the inner envelope membrane by invagination followed by vesicle traffic and/or lateral transfer of membrane constituents (e.g. Mühlethaler and Frey-Wyssling, 1959; von Wettstein, 1959; Hoober et al., 1991). Several putative components for the vesicle trafficking have been identified (Hugueney et al., 1995; Kroll et al., 2001; Wang et al., 2004), although the mode of their functions remains elusive. Overall, molecular details of thylakoid development are not yet fully understood.Proteins found in thylakoid membranes are encoded in either the chloroplast or nuclear genome, whereas lumenal proteins are encoded exclusively in the nucleus (Robinson and Mant, 2005). All of the nuclear-encoded thylakoid proteins identified so far are synthesized on cytosolic ribosomes with N-terminal extensions called transit peptides. These precursor proteins first traverse the double-membrane envelope via the general import machinery called the TOC and TIC complexes (for translocon at the outer- and inner-envelope-membranes of chloroplasts; Schnell et al., 1997), and their transit peptides are removed by a soluble metalloprotease, stromal processing peptidase (Richter et al., 2005). Extensive biochemical and genetic studies have identified four distinct pathways in the stroma to mediate sorting of these nuclear-encoded proteins to thylakoids (Robinson and Mant, 2005; Cline and Dabney-Smith, 2008). The cpSec (for chloroplast Sec) and cpTat (for chloroplast twin-arginine translocation) pathways catalyze protein targeting to the lumen. The cpSRP (for chloroplast signal recognition particle) pathway mediates sorting of the most abundant membrane proteins, LHCPs (for light-harvesting chlorophyll binding proteins), whereas a nonassisted spontaneous pathway targets several other integral membrane proteins in thylakoids. All known nuclear-encoded substrates of cpSec (e.g. OE33 [for oxygen evolving complex subunit 33] and plastocyanin), cpTat (e.g. OE23, OE17, and PsaN), and some spontaneous (e.g. CFoII, PsbW, and PsbX) pathways carry a cleavable thylakoid-targeting signal peptide that follows the stroma-targeting transit peptide in their N termini (Robinson and Mant, 2005). The signal peptides are necessary for the intraorganellar targeting and are removed in the lumen by a type I signal peptidase (SPase I) called thylakoidal processing peptidase (TPP).SPases I are membrane-bound Ser proteases responsible for cleavage of intracellular and/or intraorganellar targeting sequences (signal peptides) from numerous proteins in both prokaryotic and eukaryotic cells (Paetzel et al., 2002). In bacteria, it was shown that signal peptide cleavage is required for some proteins to be released from the plasma membrane during or after their translocation from the cytoplasm (Dalbey and Wickner, 1985), and SPases I are essential for viability (Date, 1983; Cregg et al., 1996; Zhang et al., 1997; Zhbanko et al., 2005). In thylakoids, by contrast, removal of the signal peptide was shown in vivo to be dispensable for the function and assembly of a chloroplast-encoded substrate, cytochrome f, of the green alga Chlamydomonas reinhardtii (Kuras et al., 1995; Baymann et al., 1999). In addition, the precursor form of spinach (Spinacia oleracea) OE33 that contains both the stroma- and thylakoid-targeting sequences was able to reconstitute oxygen evolution activity in vitro (Popelkova et al., 2002). Nonetheless, the importance of signal peptide cleavage for thylakoid biogenesis remains largely unexplored. In 1998, the first plant TPP cDNA was identified from Arabidopsis (Arabidopsis thaliana) seedlings based on similarity of the encoded protein to a cyanobacterial SPase I in its sequence (Chaal et al., 1998). An immunoblot assay showed thylakoid localization of this protein (At2g30440), and an in vitro assay confirmed its processing activity against wheat (Triticum aestivum) OE23 (Chaal et al., 1998). More recent genetic and immunological studies showed that a second TPP isoform in Arabidopsis, named plastidic type I signal peptidase 1 (Plsp1), is involved in processing of an envelope protein, Toc75, and a lumenal protein, OE33 (Inoue et al., 2005; Shipman and Inoue, 2009). The genetic study also showed that Plsp1 is necessary for proper thylakoid development (Inoue et al., 2005), although the mode of its action remains elusive.In this work, we conducted a more extensive characterization of plsp1-1 plastids to demonstrate the significance of protein maturation for thylakoid development. Disruption of the PLSP1 gene led to a reduction in the level of thylakoid proteins and to accumulation of improperly processed forms of multiple lumenal proteins, in addition to those of OE33 and Toc75. Plastids lacking Plsp1 accumulated stroma-localized vesicles of various sizes, at which OE33 was present. Finally, we used a genetic complementation system to show that complete maturation of the envelope protein Toc75 is dispensable for proper plant development. These results suggest that the maturation of lumenal proteins may be necessary for proper development of thylakoids.     

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.     

盐胁迫下苜蓿中盐蛋白的诱导产生

盐胁迫下苜蓿叶片中蛋白质的合成受到抑制,而其离体叶绿体中蛋白质合成增强,ABA阻碍了后者的蛋白质合成。NaCl胁迫下,“松江”和“肇东”两品种的根和叶中均无新多肽出现。在盐敏感的“松江”品种离体叶绿体中,NaGl诱导70,65,60和43kD4种多肽产生,ABA诱导60和17kD两种多肽产生;在较抗盐的“肇东”品种离体叶绿体中,NaGl诱导83,80kD和43kD3种多肽产生,但100mmol/L NaCl并不诱导83kD多肽出现,ABA无明显作用。两品种的43kD多肽和肇东品种的80kD多肽都存在于类囊体膜上,而松江品种的60kD多肽则存在于叶绿体间质中。     

Newly Imported Rieske Iron-Sulfur Protein Associates with Both Cpn60 and Hsp70 in the Chloroplast Stroma

The precursor of the Rieske FeS protein, a thylakoid membrane protein, was imported by isolated pea chloroplasts, and the mature protein was shown to be integrated into the cytochrome bf complex of the thylakoid membranes. Insertion into the thylakoid membrane was sensitive to the ionophores nigericin and valinomycin, suggesting a requirement for a proton motive force. A considerable proportion of the imported Rieske protein was detected in the stromal fraction of the chloroplasts, and this increased when membrane insertion was blocked with ionophores. Electrophoresis of the stromal fraction under nondenaturing conditions resolved two distinct complexes containing the Rieske protein. One of these complexes was identified as an association of the Rieske protein with the chaperonin Cpn60 complex by its electrophoretic mobility, Mg-ATP-dependent dissociation, and immunoprecipitation with anti-Cpn60 antibodies. Coimmunoprecipitation of imported Rieske protein with anti-heat shock protein 70 (Hsp70) antibodies indicated that the Rieske protein was also associated, in an ATP-dissociable form, with a chloroplast Hsp70 homolog. Immunoprecipitation analysis of an import time course detected the highest amounts of the Cpn60-Rieske protein complex early in the time course, whereas highest amounts of the Hsp70-Rieske protein complex were formed much later. The disappearance of the Cpn60-Rieske protein complex correlated with increased amounts of the Rieske protein in the thylakoid fraction.     

Chloroplast FtsY, chloroplast signal recognition particle, and GTP are required to reconstitute the soluble phase of light-harvesting chlorophyll protein transport into thylakoid membranes.

The integration of light-harvesting chlorophyll proteins (LHCPs) into the thylakoid membrane proceeds in two steps. First, LHCP interacts with a chloroplast signal recognition particle (cpSRP) to form a soluble targeting intermediate called the transit complex. Second, LHCP integrates into the thylakoid membrane in the presence of GTP, at least one other soluble factor, and undefined membrane components. We previously determined that cpSRP is composed of 43- and 54-kDa polypeptides. We have examined the subunit stoichiometry of cpSRP and find that it is trimeric and composed of two subunits of cpSRP43/subunit of cpSRP54. A chloroplast homologue of FtsY, an Escherichia coli protein that is critical for the function of E. coli SRP, was found largely in the stroma unassociated with cpSRP. When chloroplast FtsY was combined with cpSRP and GTP, the three factors promoted efficient LHCP integration into thylakoid membranes in the absence of stroma, demonstrating that they are all required for reconstituting the soluble phase of LHCP transport.     

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.