Precursors to two nuclear-encoded chloroplast proteins bind to the outer envelope membrane before being imported into chloroplasts

Precursor forms of chloroplast proteins synthesized in cell-free translation systems can be imported posttranslationally into isolated, intact chloroplasts. Radiochemically pure precursors to the small subunit of ribulose-1,5-bisphosphate carboxylase and to the light-harvesting chlorophyll a/b protein have been prepared by in vitro translation of hybrid-selected mRNA and used to study this import process. If chloroplasts are pretreated with the uncoupler nigericin, import does not occur, but the precursors bind to the chloroplast surface. Reincubation of the precursor-chloroplast complex in the presence of ATP results in import of bound precursors. The binding appears to be mediated by proteins of the outer chloroplast envelope membrane because pretreatment of chloroplasts with protease inhibits their ability to bind as well as to import precursors. These results indicate that at least a portion of the observed binding is to functional receptor proteins involved in the import process.     

Transport of proteins into chloroplasts

The import of cytoplasmically synthesized proteins into chloroplasts involves an interaction between at least two components; the precursor protein, and the import apparatus in the chloroplast envelope membrane. This review summarizes the information available about each of these components. Precursor proteins consist of an amino terminal transit peptide attached to a passenger protein. Transit peptides from various precurosrs are diverse with respect to length and amino acid sequence; analysis of their sequences has not revealed insight into their mode of action. A variety of foreign passenger proteins can be imported into chloroplasts when a transit peptide is present at the amino terminus. However, foreign passenger proteins are not imported as efficiently as natural passenger proteins, and some chimeric precursor proteins are not imported into chloroplasts at all. Therefore, the passenger protein, as well as the transit peptide, influences the import process. Import begins by binding of the precursor to the chloroplast surface. It has been suggested that this binding is mediated by a receptor, but evidence to support this hypothesis remains incomplete and a receptor protein has not yet been characterized. Protein translocation requires energy derived from ATP hydrolysis, although there are conflicting reports as to where hydrolysis occurs and it is unclear how this energy is utilized. The mechanism(s) whereby proteins are translocated across either the two envelope membranes or the thylakoid membrane is not known.Abbreviations EPSP 5-enolpyruvyulshikimate-3-phosphate - LHCP Chlorophyll a/b binding protein of the light-harvesting complex - NPT-II Neomycin phosphotransferase II - PC Plastocyanin - Pr Precursor - Rubisco Ribulose-1,5,-bisphosphate carboxylase/oxygenase - SS Small subunit of Rubisco     

Temperature-dependent binding to the thylakoid membranes of nuclear-coded chloroplast heat-shock proteins

Two nuclear-coded heat-shock proteins (HSP) of pea (Pisum sativum) are synthesized as larger precursors of 26 kDa and 30 kDa in vitro. They are transported post-translationally into isolated, homologous chloroplasts where they are processed to mature proteins of 22 kDa and 25 kDa, respectively. When the chloroplasts used for the transport are isolated from control plants grown at 25 degrees C the 22-kDa and 25-kDa HSPs are located in the stroma of the chloroplasts. However, when chloroplasts are prepared from heat-shocked plants both proteins are found bound to the thylakoid membranes. The transition of the non-binding to the binding status is comparatively sharp and occurs between 36 degrees C and 40 degrees C in the variety 'Rosa Krone'. The transition temperature has been determined at 38 degrees C for 'Rosa Krone' and at 40 degrees C for the variety 'Golf'. At 42 degrees C, 15-min treatment of the plants is sufficient to induce membrane binding, which persists for at least 4-6 h (but not for 24 h) after return to the ambient temperature. Once lost, membrane binding can be reinduced by a second heat-shock treatment in vivo. High light intensities during the heat shock interfere with the binding capacity for heat-shock proteins.     

Targeting of proteins to the outer envelope membrane uses a different pathway than transport into chloroplasts.

The chloroplastic envelope is composed of two membranes, inner and outer, each with a distinct set of polypeptides. Like proteins in other chloroplastic compartments, most envelope proteins are synthesized in the cytosol and post-translationally imported into chloroplasts. Considerable knowledge has been obtained concerning protein import proteins. We isolated a cDNA clone from pea that encodes a 14-kilodalton outer envelope membrane protein. The precursor form of this protein does not possess a cleavable transit peptide and its import into isolated chloroplasts does not require either ATP or a thermolysin-sensitive component on the chloroplastic surface. These findings, together with similar observations made with a spinach chloroplastic outer membrane protein, led us to propose that proteins destined for the outer membrane of the chloroplastic envelope follow an import pathway distinct from that followed by proteins destined for other chloroplastic compartments.     

Several proteins imported into chloroplasts form stable complexes with the GroEL-related chloroplast molecular chaperone.

Nine different proteins were imported into isolated pea chloroplasts in vitro. For seven of these [the large and small subunits of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco), beta-subunit of ATP synthase, glutamine synthetase, the light-harvesting chlorophyll a/b binding protein, chloramphenicol acetyltransferase, and pre-beta-lactamase], a fraction was found to migrate as a stable high-molecular-weight complex during nondenaturing gel electrophoresis. This complex contained the mature forms of the imported proteins and the groEL-related chloroplast chaperonin 60 (previously known as Rubisco subunit binding protein). Thus, the stable association of imported proteins with this molecular chaperone is widespread and not necessarily restricted to Rubisco subunits or to chloroplast proteins. With two of the imported proteins (ferredoxin and superoxide dismutase), such complexes were not observed. It seems likely that, in addition to its proposed role in assembly of Rubisco, the chloroplast chaperonin 60 is involved in the assembly or folding of a wide range of proteins in chloroplasts.     

The early light-inducible proteins of barley. Characterization of two families of 2-h-specific nuclear-coded chloroplast proteins

Within 1-2 h of illumination of etiolated barley plants the mRNAs of seven nuclear-coded proteins are transiently induced. It is proposed that at least some of these proteins are precursors to chloroplast membrane proteins since after posttranslational transport 2-h-specific bands of 18.5 kDa, 18 kDa and 13.5 kDa have been found bound to thylakoid membranes. cDNA clones for these early light-inducible proteins (ELIPs) have been isolated. Hybrid-release translation shows that part of their information must be homologous since the complete set of early light-inducible translation products is obtained with all investigated clones although the proportions of the translated bands vary for individual clones. From hybridization data it is concluded that two ELIP families of high (24-27 kDa) and of low (16-18 kDa) molecular mass exist which are induced in parallel. Induction of ELIPs occurs even at very low light intensities and is saturated at about 1000 lx. Therefore, ELIPs are not considered to represent light stress proteins but to play a regulatory role during development.     

Transport of proteins into chloroplasts. Delineation of envelope "transit" and thylakoid "transfer" signals within the pre-sequences of three imported thylakoid lumen proteins.

The targeting of cytosolically synthesized proteins into the thylakoid lumen is mediated by an aminoterminal pre-sequence consisting of an "envelope transit" and a "thylakoid transfer" signal in tandem. We have investigated the structural characteristics of several thylakoid transfer signals by determining the intermediate sites at which the stromal processing peptidase cleaves to remove the transit sequences. Using this approach we have found that the thylakoid transfer signals of Silene pratensis plastocyanin, 23-kDa oxygen-evolving complex protein from wheat, and 33-kDa oxygen-evolving complex protein from wheat, are 25, 39, and 48 residues in length, respectively. All of the transfer signals contain hydrophobic core sequences and a "-3,-1" motif reminiscent of those found in signal sequences, but the amino-terminal regions of the transfer signals of the 23- and 33-kDa proteins are both longer and more highly charged. The net charge of each amino-terminal region of the transfer sequences is +1, including the amino-terminal amino group. In each case, the stromal processing peptidase cleaves immediately after a positively charged residue, but otherwise the cleavage sites exhibit no common elements of either primary or secondary structure.     

Transport of proteins into chloroplasts. Requirements for the efficient import of two lumenal oxygen-evolving complex proteins into isolated thylakoids

The 33- and 23-kDa proteins of the photosynthetic oxygen-evolving complex are synthesized in the cytosol and targeted into the thylakoid lumen by bipartite presequences. In this report, we describe conditions for the efficient import of each of these proteins by isolated pea thylakoids. Import of the 33-kDa protein requires both light and stromal extract. The probable function of the stromal extract is to provide stromal processing peptidase to remove the first "envelope transit" signal of the presequence. Import of the 23-kDa protein is also driven by light, but stromal extract is not required for import; furthermore, efficient import is still observed if the precursor is modified to completely block cleavage by residual stromal processing peptidase activity. The intermediate form of the 23-kDa protein, which is generated by incubation of the precursor protein with stromal processing peptidase, is also efficiently imported. The results indicate that the thylakoidal protein transport system can import both the precursor and intermediate forms of the 23-kDa protein, but probably only the intermediate form of the 33-kDa protein.     

Transport of isoprenoid intermediates across chloroplast envelope membranes

The common precursor for isoprenoid biosynthesis in plants, isopentenyl diphosphate (IPP), is synthesized by two pathways, the cytosolic mevalonate pathway and the plastidic 1-deoxy-D-xylulose 5-phosphate/methylerythritol phosphate (DOXP/MEP) pathway. The DOXP/MEP pathway leads to the formation of various phosphorylated intermediates, including DOXP, 4-hydroxy-3-methylbutenyl diphosphate (HMBPP), and finally IPP. There is ample evidence for metabolic cross-talk between the two biosynthetic pathways. The present study addresses the question whether isoprenoid intermediates could be exchanged between both compartments by members of the plastidic phosphate translocator (PT) family that all mediate a counter-exchange between inorganic phosphate and various phosphorylated compounds. Transport experiments using intact chloroplasts, liposomes containing reconstituted envelope membrane proteins or recombinant PT proteins showed that HMBPP is not exchanged between the cytosol and the chloroplasts and that the transport of DOXP is preferentially mediated by the recently discovered plastidic transporter for pentose phosphates, the xylulose 5-phosphate translocator. Evidence is presented that transport of IPP does not proceed via the plastidic PTs although IPP transport is strictly dependent on various phosphorylated compounds on the opposite side of the membrane. These phosphorylated trans compounds are, in part, also used as counter-substrates by the plastidic PTs but appear to only trans activate IPP transport without being transported.     

On the translocation of proteins across the chloroplast envelope

Most of the chloroplast proteins are coded for in the nucleus and are synthesized in the cytosol from where they are subsequently transported into the different chloroplast compartments. The structural properties of the N-terminal extensions (transit peptides) of these nuclear-coded precursor proteins are discussed as well as the energy requirements for their translocation and the involvement of receptor proteins and that of other (ATP-dependent) factors.     

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.     

Targeting of proteins into chloroplasts

Cytoplasmically synthesized proteins are directed into chloroplasts by amino terminal transit sequences of the precursor proteins. For proteins of the thylakoid lumen, transit sequences are also important in directing proteins to the lumen.     

Targeting of proteins into chloroplasts

Most chloroplastic proteins are synthesized in the cytoplasm and are transported to their proper location as a posttranslational event. In the present paper we briefly review some aspects of this transport process. Because chloroplasts contain six different locations, one interesting aspect of protein targeting into chloroplasts that we consider is how precursor proteins are targeted to these various locations. One step shared by many proteins is transport across the envelope membranes. Although this process has been well studied, the components of the apparatus that mediate this transport step are mostly unidentified. Strategies to identify components of this transport apparatus are considered.     

Import of preproteins into the chloroplast inner envelope membrane

The chloroplast inner envelope membrane contains many integral proteins which differ in the number of alpha-helices that anchor the protein into the bilayer. For most of these proteins it is not known which pathway they engage to reach their final localisation within the membrane. In yeast mitochondria, two distinct sorting/insertion pathways have been described for integral inner membrane proteins, involving the Tim22 and Tim23 translocases. These routes involve on the one hand a conservative sorting, on the other hand a stop-transfer pathway. In this study we performed a systematic characterisation of the import behaviour of seven inner envelope proteins representing different numbers of predicted alpha-helices. We investigated their energy dependence, import rate, involvement of components of the chloroplast general import pathway and distribution between soluble and membrane fractions. Our results show the existence of at least two different families of inner envelope proteins that can be classified due to the occurrence of an intermediate processing form. Each of the proteins we investigated seems to use a stop-transfer pathway for insertion into the inner envelope.     

Chloroplast envelope proteins are encoded by the chloroplast genome of Chlamydomonas reinhardtii.

To characterize envelope proteins encoded by the chloroplast genome, envelopes were isolated from Chlamydomonas reinhardtii cells labeled with [35S] sulfate while blocking synthesis by cytoplasmic ribosomes. One and two-dimensional gel electrophoresis of envelopes and fluorography revealed four highly labeled proteins. Two with masses of 29 and 30 kDa and pI 5.5 were absent from the stroma and thylakoid fractions, while the others at 54 kDa, pI 5.2 and 61 kDa, pI 5.4 were detected there in smaller amounts. The 29- and 30-kDa proteins were associated with outer envelope membranes separated from inner envelope membranes after chloroplast lysis in hypertonic solution. A 32-kDa protein not labeled by [35S]sulfate was found exclusively in the inner membrane fraction, suggesting the existence of a phosphate translocator in C. reinhardtii. To identify envelope proteins exposed on the chloroplast surface, isolated active chloroplasts were surface-labeled with 125I and lactoperoxidase. The 54-kDa, pI 5.2 protein as well as a protein corresponding to either of the 29- or 30-kDa proteins described above were among the labeled components. These results show that envelope proteins of C. reinhardtii are encoded by the chloroplast genome and two are located on the outer envelope membranes.