Travelling of proteins through membranes: translocation into chloroplasts

 Most proteins involved in plastid biogenesis are encoded by the nuclear genome. They are synthesised in the cytosol and have to be transported toward and subsequently translocated into the organelle. This targeting and import process is initiated by a specific chloroplast-targeting signal. The targeting signal of the preprotein is recognised and modified by cytosolic proteins which function in transport toward the chloroplast and in maintaining the import-competent state of the preprotein. The precursor is transferred onto a multi-component complex in the outer envelope of the chloroplasts, which is formed by receptor proteins and the translocation channel. Some proteins, not containing transit sequences, are directly sorted into the outer membrane whereas the majority, containing transit sequences, will be translocated into the stroma. This involves the joint action of a protein complex in the outer envelope, one complex in the inner envelope, and soluble proteins in the intermembrane space and the stroma. The origin of this translocation complex following the endosymbiotic events is an unsolved question. Recent identification of homologous proteins to some members of this machinery in the cyanobacterium Synechocystis PCC6803 gives an initial insight into the origin of the translocation complex. Received: 27 December 1999 / Accepted: 29 March 2000     

From nuclear genes to chloroplast localized proteins

There is broad evidence that an endosymbiotic uptake of a cyanobacterial-type organism was the point of origin for the evolution of chloroplasts. During organelle evolution extensive gene transfer from the symbiont to the host genome occurred, which raises the question of how these gene products, namely proteins, which are still functional in chloroplasts, find their way back ‘home’. Nuclear-encoded proteins enter plastids via a complex import machinery that requires the coordinate interplay of a variety of soluble and membrane-bound factors on the cytosolic site as well as on the stromal side of the chloroplast envelope membranes. We define that the process called ‘import of chloroplast precursor proteins’ begins with the release of the polypeptide from the ribosomes and binding to cytosolic factors, such as a guidance complex, which accompanies (chaperones) proteins to chloroplasts. The translocation across the envelope membranes engages distinct translocation machineries at the outer and the inner envelope membranes. Additionally subsequent sorting events to different subcompartments within the plastids are operated by a number of distinct pathways, all of which seem to involve multiple subunits, which are largely of bacterial (symbiotic) origin. The evolutionary history of proteins mediating the import of chloroplast constituents across the envelope membranes seems more diverse. Since cyanobacteria lack a protein import pathway, it is not surprising that only a few subunits of the chloroplast translocon seem to be of symbiotic origin while others seem to be eukaryotic additions.     

Mechanism of protein import across the chloroplast envelope

The development and maintenance of chloroplasts relies on the contribution of protein subunits from both plastid and nuclear genomes. Most chloroplast proteins are encoded by nuclear genes and are post-translationally imported into the organelle across the double membrane of the chloroplast envelope. Protein import into the chloroplast consists of two essential elements: the specific recognition of the targeting signals (transit sequences) of cytoplasmic preproteins by receptors at the outer envelope membrane and the subsequent translocation of preproteins simultaneously across the double membrane of the envelope. These processes are mediated via the co-ordinate action of protein translocon complexes in the outer (Toc apparatus) and inner (Tic apparatus) envelope membranes.     

Toc, Tic, and chloroplast protein import.

The vast majority of chloroplast proteins are synthesized in precursor form on cytosolic ribosomes. Chloroplast precursor proteins have cleavable, N-terminal targeting signals called transit peptides. Transit peptides direct precursor proteins to the chloroplast in an organelle-specific way. They can be phosphorylated by a cytosolic protein kinase, and this leads to the formation of a cytosolic guidance complex. The guidance complex--comprising precursor, hsp70 and 14-3-3 proteins, as well as several unidentified components--docks at the outer envelope membrane. Translocation of precursor proteins across the envelope is achieved by the joint action of molecular machines called Toc (translocon at the outer envelope membrane of chloroplasts) and Tic (translocon at the inner envelope membrane of chloroplasts), respectively. The action of the Toc/Tic apparatus requires the hydrolysis of ATP and GTP at different levels, indicating energetic requirements and regulatory properties of the import process. The main subunits of the Toc and Tic complexes have been identified and characterized in vivo, in organello and in vitro. Phylogenetic evidence suggests that several translocon subunits are of cyanobacterial origin, indicating that today's import machinery was built around a prokaryotic core.     

Toc,tic, and chloroplast protein import

The vast majority of chloroplast proteins are synthesized in precursor form on cytosolic ribosomes. Chloroplast precursor proteins have cleavable, N-terminal targeting signals called transit peptides. Transit peptides direct precursor proteins to the chloroplast in an organelle-specific way. They can be phosphorylated by a cytosolic protein kinase, and this leads to the formation of a cytosolic guidance complex. The guidance complex--comprising precursor, hsp70 and 14-3-3 proteins, as well as several unidentified components--docks at the outer envelope membrane. Translocation of precursor proteins across the envelope is achieved by the joint action of molecular machines called Toc (translocon at the outer envelope membrane of chloroplasts) and Tic (translocon at the inner envelope membrane of chloroplasts), respectively. The action of the Toc/Tic apparatus requires the hydrolysis of ATP and GTP at different levels, indicating energetic requirements and regulatory properties of the import process. The main subunits of the Toc and Tic complexes have been identified and characterized in vivo, in organello and in vitro. Phylogenetic evidence suggests that several translocon subunits are of cyanobacterial origin, indicating that today's import machinery was built around a prokaryotic core.     

Protein import into chloroplasts

Most chloroplastic proteins are encoded in the nucleus, synthesized on cytosolic ribosomes and subsequently imported into the organelle. In general, proteins destined for the chloroplast are synthesized as precursor proteins with a cleavable N-terminal presequence that mediates routing to the inside of the chloroplast. These precursor proteins have to be targeted to the correct organellar membrane surface after their release from the ribosome and furthermore they have to be maintained in a conformation suitable for translocation across the two envelope membranes. Recognition and import of most chloroplastic precursor proteins are accomplished by a jointly used translocation apparatus. Different but complementary studies of several groups converged recently in the identification of the outer envelope proteins OEP86, OEP75, OEP70 (a Hsp 70-related protein), OEP34, and of the inner envelope protein IEP110 as components of this translocation machinery. None of these proteins, except for OEP70, shows any homology to components of other protein translocases. The plastid import machinery thus seems to be an original development in evolution. Following translocation into the organelle, chloroplastic proteins are sorted to their suborganellar destination, i.e., the inner envelope membrane, the thylakoid membrane, and the thylakoid lumen. This structural and evolutionary complexity of chloroplasts is reflected by a variety of routing mechanisms by which proteins reach their final location once inside the organelle. This review will focus on recent advances in the identification of components of the chloroplastic protein import machinery, and new insights into the pathways of inter-and intraorganellar sorting.     

Protein import into chloroplasts.

Chloroplasts have evolved an elaborate system of membrane and soluble subcompartments to organize and regulate photosynthesis and essential aspects of amino acid and lipid metabolism. The biogenesis and maintenance of organellar architecture rely on protein subunits encoded by both nuclear and plastid genomes. Import of nuclear-encoded proteins is mediated by interactions between the intrinsic N-terminal transit sequence of the nuclear-encoded preprotein and a common import machinery at the chloroplast envelope. Recent investigations have shown that there are two unique membrane-bound translocation systems, in the outer and inner envelope membranes, which physically associate during import to transport preproteins from the cytoplasm to the internal stromal compartment. This review discusses current understanding of these translocation systems and models for the way in which they might function.     

Analysis of the Interactions of Preproteins with the Import Machinery over the Course of Protein Import into Chloroplasts

We have investigated the interactions of two nuclear-encoded preproteins with the chloroplast protein import machinery at three stages in import using a label-transfer crosslinking approach. During energy-independent binding at the outer envelope membrane, preproteins interact with three known components of the outer membrane translocon complex, Toc34, Toc75, and Toc86. Although Toc75 and Toc86 are known to associate with preproteins during import, a role for Toc34 in preprotein binding previously had not been observed. The interaction of Toc34 with preproteins is regulated by the binding, but not hydrolysis of GTP. These data provide the first evidence for a direct role for Toc34 in import, and provide insights into the function of GTP as a regulator of preprotein recognition. Toc75 and Toc86 are the major targets of cross-linking upon insertion of preproteins across the outer envelope membrane, supporting the proposal that both proteins function in translocation at the outer membrane as well as preprotein recognition. The inner membrane proteins, Tic(21) and Tic22, and a previously unidentified protein of 14 kD are the major targets of crosslinking during the late stages in import. These data provide additional support for the roles of these components during protein translocation across the inner membrane. Our results suggest a defined sequence of molecular interactions that result in the transport of nuclear-encoded preproteins from the cytoplasm into the stroma of chloroplasts.     

Protein translocation across chloroplast envelope membranes

Nuclear-encoded chloroplast proteins are imported from the cytosol into the chloroplast stroma by a common translocation machinery. Several components of the import apparatus, including GTP-binding proteins and Hsp70 proteins, have recently been identified and characterized. This review discusses the role of these proteins in chloroplast protein import.     

Tic22 is targeted to the intermembrane space of chloroplasts by a novel pathway.

Tic22 previously was identified as a component of the general import machinery that functions in the import of nuclear-encoded proteins into the chloroplast. Tic22 is peripherally associated with the outer face of the inner chloroplast envelope membrane, making it the first known resident of the intermembrane space of the envelope. We have investigated the import of Tic22 into isolated chloroplasts to define the requirements for targeting of proteins to the intermembrane space. Tic22 is nuclear-endoded and synthesized as a preprotein with a 50-amino acid N-terminal presequence. The analysis of deletion mutants and chimerical proteins indicates that the precursor of Tic22 (preTic22) presequence is necessary and sufficient for targeting to the intermembrane space. Import of preTic22 was stimulated by ATP and required the presence of protease-sensitive components on the chloroplast surface. PreTic22 import was not competed by an excess of an authentic stromal preprotein, indicating that targeting to the intermembrane space does not involve the general import pathway utilized by stromal preproteins. On the basis of these observations, we conclude that preTic22 is targeted to the intermembrane space of chloroplasts by a novel import pathway that is distinct from known pathways that target proteins to other chloroplast subcompartments.     

Effects of osmotic preconditioning on nuclear replication activity in seeds of pepper (Capsicum annuum)

Routing of cytosolically synthesized precursor proteins into chloroplasts is a specific process which involves a multitude of soluble and membrane components. In this review we wil1 focus on early events of the translocation pathway of nuclear coded plastidic precursor proteins and compare import routes for polypeptide of the outer chloroplast envelope to that of internal chloroplast compartments. A number of proteins housed in the chloroplast envelopes have been implied to be involved in the translocation process, but so far a certain function has not been assigned to any of these proteins. The only exception could be an envelope localized hsc 70 homologue which could retain the import competence of a precursor protein in transit into the organelle.     

Specific lipids influence the import capacity of the chloroplast outer envelope precursor protein translocon

Recent studies demonstrated that lipids influence the assembly and efficiency of membrane-embedded macromolecular complexes. Similarly, lipids have been found to influence chloroplast precursor protein binding to the membrane surface and to be associated with the Translocon of the Outer membrane of Chloroplasts (TOC). We used a system based on chloroplast outer envelope vesicles from Pisum sativum to obtain an initial understanding of the influence of lipids on precursor protein translocation across the outer envelope. The ability of the model precursor proteins p(OE33)titin and pSSU to be recognized and translocated in this simplified system was investigated. We demonstrate that transport across the outer membrane can be observed in the absence of the inner envelope translocon. The translocation, however, was significantly slower than that observed for chloroplasts. Enrichment of outer envelope vesicles with different lipids natively found in chloroplast membranes altered the binding and transport behavior. Further, the results obtained using outer envelope vesicles were consistent with the results observed for the reconstituted isolated TOC complex. Based on both approaches we concluded that the lipids sulfoquinovosyldiacylglycerol (SQDG) and phosphatidylinositol (PI) increased TOC-mediated binding and import for both precursor proteins. In contrast, enrichment in digalactosyldiacylglycerol (DGDG) improved TOC-mediated binding for pSSU, but decreased import for both precursor proteins. Optimal import occurred only in a narrow concentration range of DGDG.     

Stromal Hsp70 Is Important for Protein Translocation into Pea and Arabidopsis Chloroplasts

Hsp70 family proteins function as motors driving protein translocation into mitochondria and the endoplasmic reticulum. Whether Hsp70 is involved in protein import into chloroplasts has not been resolved. We show here Arabidopsis thaliana knockout mutants of either of the two stromal cpHsc70s, cpHsc70-1 and cpHsc70-2, are defective in protein import into chloroplasts during early developmental stages. Protein import was found to be affected at the step of precursor translocation across the envelope membranes. From solubilized envelope membranes, stromal cpHsc70 was specifically coimmunoprecipitated with importing precursors and stoichiometric amounts of Tic110 and Hsp93. Moreover, in contrast with receptors at the outer envelope membrane, cpHsp70 is important for the import of both photosynthetic and nonphotosynthetic proteins. These data indicate that cpHsc70 is part of the chloroplast translocon for general import and is important for driving translocation into the stroma. We further analyzed the relationship of cpHsc70 with the other suggested motor system, Hsp93/Tic40. Chloroplasts from the cphsc70-1 hsp93-V double mutant had a more severe import defect than did the single mutants, suggesting that the two proteins function in parallel. The cphsc70-1 tic40 double knockout was lethal, further indicating that cpHsc70-1 and Tic40 have an overlapping essential function. In conclusion, our data indicate that chloroplasts have two chaperone systems facilitating protein translocation into the stroma: the cpHsc70 system and the Hsp93/Tic40 system.     

Identification of intermediates in the pathway of protein import into chloroplasts and their localization to envelope contact sites

We have used a hybrid precursor protein to study the pathway of protein import into chloroplasts. This hybrid (pS/protA) consists of the precursor to the small subunit of Rubisco (pS) fused to the IgG binding domains of staphylococcal protein A. The pS/protA is efficiently imported into isolated chloroplasts and is processed to its mature form (S/protA). In addition to the mature stromal form, two intermediates in the pathway of pS/protA import were identified at early time points in the import reaction. The first intermediate represents unprocessed pS/protA bound to the outer surface of the chloroplast envelope and is analogous to a previously characterized form of pS that is specifically bound to the chloroplast surface and can be subsequently translocated in the stroma (Cline, K., M. Werner-Washburne, T. H. Lubben, and K. Keegstra. 1985. J. Biol. Chem. 260:3691-3696.) The second intermediate represents a partially translocated form of the precursor that remains associated with the envelope membrane. This form is processed to mature S/protA, but remains susceptible to exogenously added protease in intact chloroplasts. We conclude that the envelope associated S/protA is spanning both the outer and inner chloroplast membranes en route to the stroma. Biochemical and immunochemical localization of the two translocation intermediates indicates that both forms are exposed at the surface of the outer membrane at sites where the outer and inner membrane are closely apposed. These contact zones appear to be organized in a reticular network on the outer envelope. We propose a model for protein import into chloroplasts that has as its central features two distinct protein conducting channels in the outer and inner envelope membranes, each gated open by a distinct subdomain of the pS signal sequence.     

Protein import into chloroplasts: new aspects of a well-known topic

Protein import into plant chloroplasts is a fascinating topic that is being investigated by many research groups. Since the majority of chloroplast proteins are synthesised as precursor proteins in the cytosol, they have to be posttranslationally imported into the organelle. For this purpose, most preproteins are synthesised with an N-terminal presequence, which is both necessary and sufficient for organelle recognition and translocation initiation. The import of preproteins is facilitated by two translocation machineries in the outer and inner envelope of chloroplasts, the Toc and Tic complexes, respectively. Translocation of precursor proteins across the envelope membrane has to be highly regulated to react to the metabolic requirements of the organelle. The aim of this review is to summarise the events that take place at the translocation machineries that are known so far. In addition, we focus in particular on alternative import pathways and the aspect of regulation of protein transport at the outer and inner envelope membrane.     

New Insights into the Protein Import Machinery of the Chloroplast's Outer Envelope

A large number of plastid localized proteins are post-translationally imported as precursor proteins from the cytosol into the organelle. Recognition and translocation is accomplished by a subset of chloroplast envelope proteins, which were identified by different but complementary methods. The o uter e nvelope p roteins OEP 86, OEP 75, OEP 70 (a heat shock cognate 70 homologue) and OEP 34 are clearly involved in the import event and can be isolated as one functionally active translocation unit. For three of these proteins cDNA clones have been very recently obtained, namely OEP 86, OEP 75 and OEP 34. OEP 86 seems to be a precursor protein receptor which could be regulated by GTP binding and ATP-dependent phosphorylation-dephosphorylation. OEP 75 is part of the translocation pore traversing the membrane in multiple β-sheets. OEP 34 is tightly associated with OEP 75. It represents a new type of GTP-binding protein which possesses endogenous GTPase activity. Multiple GTP binding and hydrolysis cycles as well as protein phosphorylation-dephosphorylation events might, therefore, regulate the interaction of a precursor protein with the translocation machinery of the outer envelope, making it very distinct from the mitochondrial outer membrane system. Further proteins of the inner envelope membrane, namely IEP 97 and IEP 36, have been implied to function in the translocation event. These recent data allow not only identification of the players in the game but also speculation about mechanisms and regulation of translocation.     

Physcomitrella patens as a model for the study of chloroplast protein transport: conserved machineries between vascular and non-vascular plants

A single general import pathway in vascular plants mediates the transport of precursor proteins across the two membranes of the chloroplast envelope, and at least four pathways are responsible for thylakoid protein targeting. While the transport systems in the thylakoid are related to bacterial secretion systems, the envelope machinery is thought to have arisen with the endosymbiotic event and to be derived, at least in part, from proteins present in the original endosymbiont. Recently the moss Physcomitrella patens has gained worldwide attention for its ability to undergo homologous recombination in the nuclear genome at rates unseen in any other land plants. Because of this, we were interested to know whether it would be a useful model system for studying chloroplast protein transport. We searched the large database of P. patens expressed sequence tags for chloroplast transport components and found many putative homologues. We obtained full-length sequences for homologues of three Toc components from moss. To our knowledge, this is the first sequence information for these proteins from non-vascular plants. In addition to identifying components of the transport machinery from moss, we isolated plastids and tested their activity in protein import assays. Our data indicate that moss and pea (Pisum sativum) plastid transport systems are functionally similar. These findings identify P. patens as a potentially useful tool for combining genetic and biochemical approaches for the study of chloroplast protein targeting. Abbreviations: EST, expressed sequence tag; LHCP, light-harvesting chlorophyll-binding protein; NIBB, National Institute for Basic Biology; OE17, 17 kDa subunit of the oxygen-evolving complex; PC, plastocyanin; PEP, Physcomitrella EST Programme; SPP, stromal processing peptidase; SRP, signal recognition particle; Tat, twin-arginine translocation; Tic, translocon at the inner membrane of the chloroplast envelope; Toc, translocon at the outer membrane of the chloroplast envelope; TPP, thylakoid processing peptidase; TPR, tetratricopeptide repeatSupplementary material to this paper is available in electronic form at .This revised version was opublished online in July 2005 with corrected page numbers.     

Energy dependence of protein translocation into chloroplasts

The translocation of in vitro synthesized precursor proteins into intact spinach chloroplasts was investigated with respect to its energy requirement. It was demonstrated that MgATP itself, and not a transmembrane electrochemical gradient across the envelope membrane, promotes protein import. By manipulating the external and the stromal level of MgATP, we provided evidence that MgATP energized the protein import not within the chloroplast but at the outside of the envelope membrane. It is postulated that an MgATP-dependent phosphorylation/dephosphorylation cycle at the outer membrane face was involved in the course of protein translocation into the chloroplast.     

A new chloroplast protein import intermediate reveals distinct translocation machineries in the two envelope membranes: energetics and mechanistic implications

Chloroplast protein import presents a complex membrane traversal problem: precursor proteins must cross two envelope membranes to reach the stromal compartment. This work characterizes a new chloroplast protein import intermediate which has completely traversed the outer envelope membrane but has not yet reached the stroma. The existence of this intermediate demonstrates that distinct protein transport machineries are present in both envelope membranes, and that they are able to operate independently of one another under certain conditions. Energetic characterization of this pathway led to the identification of three independent energy-requiring steps: binding of the precursor to the outer envelope membrane, outer membrane transport, and inner membrane transport. Localization of the sites of energy utilization for each of these steps, as well as their respective nucleotide specificities, suggest that three different ATPases mediate chloroplast envelope transport.     

The Chloroplast Outer Envelope Membrane： The Edge of Liaht and Excitement

The chloroplast is surrounded by a double-membrane envelope at which proteins, ions, and numerous metabolites including nucleotides, amino acids, fatty acids, and carbohydrates are exchanged between the two aqueous phases, the cytoplasm and the chloroplast stroma. The chloroplast envelope is also the location where the biosynthesis and accumulation of various lipids take place. By contrast to the inner membrane, which contains a number of specific transporters and acts as the permeability barrier, the chloroplast outer membrane has often been considered a passive compartment derived from the phagosomal membrane. However, the presence of galactoglycerolipids and β-barrel membrane proteins support the common origin of the outer membranes of the chloroplast envelope and extant cyanobacteria. Furthermore, recent progress in the field underlines that the chloroplast outer envelope plays important roles not only for translocation of various molecules, but also for regulation of metabolic activities and signaling processes. The chloroplast outer envelope membrane offers various interesting and challenging questions that are relevant to the understanding of organelle biogenesis, plant growth and development, and also membrane biology in general.