Identification of a signal that distinguishes between the chloroplast outer envelope membrane and the endomembrane system in vivo

Certain small outer envelope membrane proteins of chloroplasts are encoded by the nuclear genome without a cleavable N-terminal transit peptide. We investigated in vivo the targeting mechanism of AtOEP7, an Arabidopsis homolog of the small outer envelope membrane protein. AtOEP7 was expressed as a fusion protein with the green fluorescent protein (GFP) either transiently in protoplasts or stably in transgenic plants. In either case, fluorescence microscopy of transformed cells and protein gel blot analysis of fractionated proteins confirmed that the AtOEP7:GFP fusion protein was targeted to the chloroplast outer envelope membrane. In vivo targeting experiments revealed that two regions, the transmembrane domain (TMD) and its C-terminal neighboring seven-amino acid region, were necessary and sufficient for targeting to the chloroplast outer membrane. Substitution of aspartic acid or lysine residues with glycine residues or scrambling of the amino acid sequence of the seven-amino acid region caused mistargeting to the plasma membrane. Although the amino acid sequence of the TMD is not important for targeting, amino acid residues with large side chains inhibited targeting to the chloroplasts and resulted in the formation of large aggregates in the protoplasts. In addition, introduction of a proline residue within the TMD resulted in inhibition of targeting. Finally, a fusion protein, AtOEP7:NLS:GFP, was targeted efficiently to the chloroplast envelope membranes despite the presence of a nuclear localization signal. On the basis of these results, we conclude that the seven-amino acid region and the TMD are determinants for targeting to the chloroplast outer envelope membrane. The seven-amino acid region plays a critical role in AtOEP7 evading the endomembrane system and entering the chloroplast pathway, and the TMD plays critical roles in migration to the chloroplasts and/or subsequent insertion into the membrane.     

The C terminus of a chloroplast precursor modulates its interaction with the translocation apparatus and PIRAC.

The import of proteins into chloroplasts involves a cleavable, N-terminal targeting sequence known as the transit peptide. Although the transit peptide is both necessary and sufficient to direct precursor import into chloroplasts, the mature domain of some precursors has been shown to modulate targeting and translocation efficiency. To test the influence of the mature domain of the small subunit of Rubisco during import in vitro, the precursor (prSSU), the mature domain (mSSU), the transit peptide (SS-tp), and three C-terminal deletion mutants (Delta52, Delta67, and Delta74) of prSSU were expressed and purified from Escherichia coli. Activity was then evaluated by competitive import of (35)S-prSSU. Both IC(50) and K(i) values consistently suggest that removal of C-terminal prSSU sequences inhibits its interaction with the translocation apparatus. Non-competitive import studies demonstrated that prSSU and Delta52 were properly processed and accumulated within the chloroplast, whereas Delta67 and Delta74 were rapidly degraded via a plastid-localized protease. The ability of prSSU-derived proteins to induce inactivation of the protein-import-related anion channel was also evaluated. Although the C-terminal deletion mutants were less effective at inducing channel closure upon import, they did not effect the mean duration of channel closure. Possible mechanisms by which C-terminal residues of prSSU modulate chloroplast targeting are discussed.     

Expression, isolation, and characterization of a chloroplast targeting peptide

For the first time a method is described in which an N-terminal targeting peptide is isolated from Escherichia coli. After overexpression, purification, and cleavage of a fusion protein the protease-sensitive transit peptide from the chloroplast precursor protein preferredoxin could be isolated by HPLC. It was characterized by N-terminal amino acid sequencing and electrospray mass spectrometry. Its functionality was suggested by in vitro import competition experiments with isolated pea chloroplasts, in which the isolated peptide inhibited the import of radioactively labeled preferredoxin. Results from import competition experiments performed with a transit peptide deletion mutant suggested that the four extreme C-terminal amino acids lack information to interact with the chloroplast import machinery.     

A 38-amino-acid sequence encompassing the arm domain of the cucumber necrosis virus coat protein functions as a chloroplast transit Peptide in infected plants

Experiments to determine the subcellular location of the coat protein (CP) of the tombusvirus Cucumber necrosis virus (CNV) have been conducted. By confocal microscopy, it was found that an agroinfiltrated CNV CP-green fluorescent protein (GFP) fusion targets chloroplasts in Nicotiana benthamiana leaves and that a 38-amino-acid (aa) region that includes the complete CP arm region plus the first 4 amino acids of the shell domain are sufficient for targeting. Western blot analyses of purified and fractionated chloroplasts showed that the 38-aa region directs import to the chloroplast stroma, suggesting that the CNV arm can function as a chloroplast transit peptide (TP) in plants. Several features of the 38-aa region are similar to features typical of chloroplast TPs, including (i) the presence of an alanine-rich uncharged region near the N terminus, followed by a short region rich in basic amino acids; (ii) a conserved chloroplast TP phosphorylation motif; (iii) the requirement that the CNV 38-aa sequence be present at the amino terminus of the imported protein; and (iv) specific proteolytic cleavage upon import into the chloroplast stroma. In addition, a region just downstream of the 38-aa sequence contains a 14-3-3 binding motif, suggesting that chloroplast targeting requires 14-3-3 binding, as has been suggested for cellular proteins that are targeted to chloroplasts. Chloroplasts of CNV-infected plants were found to contain CNV CP, but only the shell and protruding domain regions were present, indicating that CNV CP enters chloroplasts during infection and that proteolytic cleavage occurs as predicted from agroinfiltration studies. We also found that particles of a CNV CP mutant deficient in externalization of the arm region have a reduced ability to establish infection. The potential biological significance of these findings is discussed.     

Targeting of proteins to the thylakoid lumen by the bipartite transit peptide of the 33 kd oxygen-evolving protein.

Various chimeric precursors and deletions of the 33 kd oxygen-evolving protein (OEE1) were constructed to study the mechanism by which chloroplast proteins are imported and targeted to the thylakoid lumen. The native OEE1 precursor was imported into isolated chloroplasts, processed and localized in the thylakoid lumen. Replacement of the OEE1 transit peptide with the transit peptide of the small subunit of ribulose-1,5-bisphosphate carboxylase, a stromal protein, resulted in redirection of mature OEE1 into the stromal compartment of the chloroplast. Utilizing chimeric transit peptides and block deletions we demonstrated that the 85 residue OEE1 transit peptide contains separate signal domains for importing and targeting the thylakoid lumen. The importing domain, which mediates translocation across the two membranes of the chloroplast envelope, is present in the N-terminal 58 amino acids. The thylakoid lumen targeting domain, which mediates translocation across the thylakoid membrane, is located within the C-terminal 27 residues of the OEE1 transit peptide. Chimeric precursors were constructed and used in in vitro import experiments to demonstrate that the OEE1 transit peptide is capable of importing and targeting foreign proteins to the thylakoid lumen.     

Both metaxin and Tom20 together with two mitochondria-specific motifs support mitochondrial targeting of dual-targeting AtSufE1

Plant cells have two endosymbiotic organelles, chloroplasts, and mitochondria. These organelles perform specific functions that depend on organelle-specific proteins. The majority of chloroplast and mitochondrial proteins are specifically imported by the transit peptide and presequence, respectively. However, a significant number of proteins are also dually targeted to these two organelles. Currently, it is not fully understood how proteins are dually targeted to both chloroplasts and mitochondria. In this study, the mechanism underlying mitochondrial targeting of dual targeting AtSufE1 in Arabidopsis was elucidated. The N-terminal fragment containing 80 residues of AtSufE1 (AtSufE1N80) was sufficient to confer dual targeting of reporter protein, AtSufE1N80:GFP, in protoplasts. Two sequence motifs, two arginine residues at 15^th and 21^st positions, and amino acid (aa) sequence motif AKTLLLRPLK from the 31^st to 40^th aa position, were responsible for targeting to mitochondria a portion of reporter proteins amid the chloroplast targeting. The sequence motif PSEVPFRRT from the 41^st to 50^th aa position constitutes a common motif for targeting to both chloroplasts and mitochondria. For mitochondrial import of AtSufE1:N80, Metaxin played a critical role. In addition, BiFC and protein pull-down experiments showed that AtSufE1N80 specifically interacts with import receptors, Metaxin and Tom20. The interaction of AtSufE1N80 with Metaxin was required for the interaction with Tom20. Based on these results, we propose that mitochondrial targeting of dual-targeting AtSufE1 is mediated by both mitochondria-specific and common sequence motifs in the signal sequence through the interaction with import receptors, Metaxin and Tom20, in a successive manner.     

The role of the N-terminal domain of chloroplast targeting peptides in organellar protein import and miss-sorting

We have analysed 385 mitochondrial and 567 chloroplastic signal sequences of proteins found in the organellar proteomes of Arabidopsis thaliana. Despite overall similarities, the first 16 residues of transit peptides differ remarkably. To test the hypothesis that the N-terminally truncated transit peptides would redirect chloroplastic precursor proteins to mitochondria, we studied import of the N-terminal deletion mutants of ELIP, PetC and Lhcb2.1. The results show that the deletion mutants were neither imported into chloroplasts nor miss-targeted to mitochondria in vitro and in vivo, showing that the entire transit peptide is necessary for correct targeting as well as miss-sorting.     

Biophysical characterization of a transit peptide directing chloroplast protein import.

We have investigated the biophysical properties of a 35 amino acid peptide representing the entire length of a chloroplastic targeting sequence. The peptide, termed gamma-tp, corresponds in sequence to the transit peptide of the gamma subunit of the chloroplast ATP synthase from Chlamydomonas reinhardtii. We found that gamma-tp blocks the import of the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase into isolated pea chloroplasts (KI approximately 5 microM), suggesting that it interacts with higher plant plastids in a physiological manner. We also found the gamma-tp to have a high affinity for nonpolar environments, but not to cause a general disruption of membrane integrity. Hydrophobic moment analysis suggests that the gamma-tp can adopt an amphipathic beta structure. However, circular dichroism measurements indicate that the peptide is largely a random coil, in both the presence and absence of sodium laurylsulfate micelles. In the absence of a recognizable secondary structural targeting motif, we asked whether the presence of a transit peptide on a chloroplast protein increases the protein's overall affinity for nonpolar environments. Phase-partition experiments with Triton X-114 suggest that this is not the case. These results are discussed in relation to the mechanism of protein targeting to chloroplasts.     

Carboxyl-terminal sequences can influence the in vitro import and intraorganellar targeting of chloroplast protein precursors.

The transit peptide of the lumenal 33-kDa oxygen-evolving polypeptide (OEE1) is capable of directing the import and targeting of the foreign protein dihydrofolate reductase (DHFR) to the thylakoid lumen. The import results from the first part of this study indicate that methotrexate cannot block the import or intraorganellar targeting of OEE1-DHFR in chloroplasts in contrast to that reported for the import of cytochrome oxidase subunit IV (COXIV)-DHFR in mitochondria. These results suggest that the fusion of the OEE1 transit sequence to DHFR affected the protein's methotrexate binding properties. We further examined and compared the transport characteristics of a number of carboxyl-terminal truncated native chloroplast precursors to determine whether carboxyl domains contribute to the import and intraorganellar targeting mechanism of these proteins. The plastid precursors chosen for this study are targeted to one of the following chloroplast compartments: the stroma, the thylakoid membrane, and the lumen. In most cases, removal of carboxyl domains had a dramatic effect on one or more stages of the translocation pathway, such as import, processing, and intraorganellar targeting. The effects of carboxyl deletions varied from precursor to precursor and were dependent on the extent of the deletion. These combined results suggest that carboxyl domains in the mature part of the proteins can influence the function of the transit peptide, and as a result play an important role in determining the import and targeting competence of chloroplast precursors.     

Chloroplast Import Signals: The Length Requirement for Translocation In Vitro and In Vivo

Protein translocation of cytosolically synthesized proteins requires signals for both targeting of precursor proteins to the surface of the respective compartment and their transfer across its membrane. In contrast to signals for peroxisomal and endoplasmic reticulum translocation, the signals for mitochondrial and chloroplast transport are less well defined with respect to length and amino acid requirements. To study the properties of signals required for translocation into chloroplasts in vitro and in vivo, we used fusion proteins composed of transit peptides and the Ig-like module of the muscle protein titin as passenger. We observed that about 60 amino acids—longer than the transit peptide length of many experimentally confirmed chloroplast proteins—are required for efficient translocation. However, within native chloroplast precursor proteins with transit peptides shorter than 60 amino acids, extension appears to be present as they are efficiently imported into organelles. In addition, the interaction of an unfolded polypeptide stretch of 60 or more amino acids with receptors at the chloroplast surface results in the unidirectionality of protein translocation into chloroplasts even in the presence of a competing C-terminal peroxisomal targeting signal. These findings prove the existing ideas that initial targeting is defined by the N-terminal signal and that the C-terminal signal is sensed only subsequently.     

Primary structure of maize pyruvate, orthophosphate dikinase as deduced from cDNA sequence

We have isolated two overlapping cDNA clones that encompass the entire structural gene for pyruvate, orthophosphate dikinase from maize. The analysis of the nucleotide sequence has revealed that the cDNA clones include an insert of a total of 3,171 nucleotides without a poly(A) tail and encode a polypeptide that contains 947 amino acid residues and has a molecular weight of 102,673. Comparison of the N-terminal amino acid sequence of purified pyruvate, orthophosphate dikinase protein with that deduced from the nucleotide sequence shows that the mature form of pyruvate, orthophosphate dikinase in the maize chloroplast consists of 876 amino acid residues and has a molecular weight of 95,353. The amino acid composition of the deduced sequence of pyruvate, orthophosphate dikinase is in good agreement with that of the purified enzyme. The region that contains the active and regulatory sites of pyruvate, orthophosphate dikinase can be found in the deduced sequence of amino acids. We have predicted the secondary structure and calculated the hydropathy pattern of this region. The extra 71 residues at the N terminus of the deduced sequence of amino acid residues corresponds to the transit peptide which is indispensable for the transport of the precursor protein into chloroplasts. We have compared the primary structure of the pyruvate, orthophosphate dikinase transit peptide to those of other proteins and found sequences similar to the consensus sequences found in other transit peptides.     

Analysis of chloroplast transit peptide function using mutations in the carboxyl-terminal region

Protein import into chloroplasts requires a transit peptide, which interacts with the chloroplast transport apparatus and leads to translocation of the protein across the chloroplast envelope. While the amino acid sequences of many transit peptides are known, functional domains have been difficult to identify. Previous studies suggest that the carboxyl terminus of the transit peptide for ribulose bisphosphate carboxylase small subunit is important for both translocation across the chloroplast envelope and proper processing of the precursor protein. We dissected this region using in vitro mutagenesis, creating a set of mutants with small changes in primary structure predicted to cause alterations in secondary structure. The import behavior of the mutant proteins was assessed using isolated chloroplasts. Our results show that removal of a conserved arginine residue in this region results in impaired processing, but does not necessarily affect import rates. In contrast, substituting amino acids with low reverse turn or amphiphilic potential for other original residues affected import rate but not processing.     

Processing of the dual targeted precursor protein of glutathione reductase in mitochondria and chloroplasts

Pea glutathione reductase (GR) is dually targeted to mitochondria and chloroplasts by means of an N-terminal signal peptide of 60 amino acid residues. After import, the signal peptide is cleaved off by the mitochondrial processing peptidase (MPP) in mitochondria and by the stromal processing peptidase (SPP) in chloroplasts. Here, we have investigated determinants for processing of the dual targeting signal peptide of GR by MPP and SPP to examine if there is separate or universal information recognised by both processing peptidases. Removal of 30 N-terminal amino acid residues of the signal peptide (GRDelta1-30) greatly stimulated processing activity by both MPP and SPP, whereas constructs with a deletion of an additional ten amino acid residues (GRDelta1-40) and deletion of 22 amino acid residues in the middle of the GR signal sequence (GRDelta30-52) could be cleaved by SPP but not by MPP. Numerous single mutations of amino acid residues in proximity of the cleavage site did not affect processing by SPP, whereas mutations within two amino acid residues on either side of the processing site had inhibitory effect on processing by MPP with a nearly complete inhibition for mutations at position -1. Mutation of positively charged residues in the C-terminal half of the GR targeting peptide inhibited processing by MPP but not by SPP. An inhibitory effect on SPP was detected only when double and triple mutations were introduced upstream of the cleavage site. These results indicate that: (i) recognition of processing site on a dual targeted GR precursor differs between MPP and SPP; (ii) the GR targeting signal has similar determinants for processing by MPP as signals targeting only to mitochondria; and (iii) processing by SPP shows a low level of sensitivity to single mutations on targeting peptide and likely involves recognition of the physiochemical properties of the sequence in the vicinity of cleavage rather than a requirement for specific amino acid residues.     

Protein trafficking to the plastid of Plasmodium falciparum is via the secretory pathway

The plastid of Plasmodium falciparum (or 'apicoplast') is the evolutionary homolog of the plant chloroplast and represents a vestige of a photosynthetic past. Apicoplast indispensability indicates that it still provides essential functions to parasites. Similar to plant chloroplasts, the apicoplast is dependent on many nucleus-encoded genes to provide these functions. The apicoplast is surrounded by four membranes, two more than plant chloroplasts. Thus, protein targeting to the apicoplast must overcome additional membrane barriers. In P.falciparum we have analyzed apicoplast targeting using green fluorescent protein (GFP). We demonstrate that protein targeting is at least a two-step process mediated by bipartite N-terminal pre-sequences that consist of a signal peptide for entry into the secretory pathway and a plant-like transit peptide for subsequent import into the apicoplast. The P.falciparum transit peptide is exceptional compared with other known plastid transit peptides in not requiring serine or threonine residues. The pre-sequence components are removed stepwise during apicoplast targeting. Targeting GFP to the apicoplast has also provided the first opportunity to examine apicoplast morphology in live P. falciparum.     

Expression and import of an active cellulase from a thermophilic bacterium into the chloroplast both in vitro and in vivo

A bacterial thermostable cellulase, the endo-1,4--D-glucanase E1 from Acidothermus cellulolyticus, was imported into chloroplasts, and an active enzyme was recovered both in vitro and in vivo. Precursor fusion proteins were synthesized with E1 or its catalytic domain, CD, fused to the transit peptide of ferredoxin or ribulose-bisphosphate carboxylase activase for stromal targeting. A spacer region of 1, 5 or 15 amino acids was included carboxy to the transit peptide. The efficiency of import and processing by the stromal processing peptidase depended on the nature of the transit peptide and the passenger protein, and increased with the length of the spacer between them. Besides finding E1 or CD in the stroma, protein was arrested in the envelope during import showing that structural features of E1 and CD, along with their proximity to the transit peptide, influence translocation. The cellulose binding domain and/or serine/proline/threoline-rich linker of E1 may impede efficient import. Significantly, most precursors for E1 and CD synthesized by in vitro translation possessed endoglucanse activity that was temperature-dependent, and required the residues AGGGY at the N-terminus of E1 and CD. Furthermore, activity was detected upon import into chloroplasts. Based on the in vitro analyses, five precursor fusion proteins were selected to determine if E1 and CD would be successfully targeted to chloroplasts in vivo. In transgenic tobacco plants, E1 and CD accumulated in both the stromal and membrane fractions and, importantly, chloroplast extracts showed endoglucanase activity.     

Non-canonical transit peptide for import into the chloroplast

The large majority of plastid proteins are nuclear-encoded and, thus, must be imported within these organelles. Unlike most of the outer envelope proteins, targeting of proteins to all other plastid compartments (inner envelope membrane, stroma, and thylakoid) is strictly dependent on the presence of a cleavable transit sequence in the precursor N-terminal region. In this paper, we describe the identification of a new envelope protein component (ceQORH) and demonstrate that its subcellular localization is limited to the inner membrane of the chloroplast envelope. Immunopurification, microsequencing of the natural envelope protein and cloning of the corresponding full-length cDNA demonstrated that this protein is not processed in the N-terminal region during its targeting to the inner envelope membrane. Transient expression experiments in plant cells were performed with truncated forms of the ceQORH protein fused to the green fluorescent protein. These experiments suggest that neither the N-terminal nor the C-terminal are essential for chloroplastic localization of the ceQORH protein. These observations are discussed in the frame of the endosymbiotic theory of chloroplast evolution and suggest that a domain of the ceQORH bacterial ancestor may have evolved so as to exclude the general requirement of an N-terminal plastid transit sequence.     

The import of ferredoxin-NADP+ reductase precursor into chloroplasts is modulated by the region between the transit peptide and the mature core of the protein.

Protein transport across organelles' membranes requires that precursor proteins adopt an unfolded structure in order to be translocated by the import machinery. Ferredoxin-NADP+ reductase precursor, as well as many others, acquires a tightly folded structure that needs to be unfolded before or during its import. Several steps of chloroplast protein import are not fully understood. In particular, the role of different regions of the precursor protein has not been completely elucidated. In this work, we have studied the import into chloroplasts of precursor proteins with inclusions of amino acid spacers between the transit peptide and the mature protein, and with deletions in the N-terminal region of the mature enzyme. We measured the import rate constants for these precursors and the results indicate that the distance between the transit peptide and the core of the mature protein determines the import kinetics. The longer precursors were imported into the organelle faster than the wild type form. Precursors with deletions in the N-terminal region of the mature protein also showed increased import rates compared to the wild type. Homology studies amongst all family members reveal that only chloroplastic proteins possess this region. We suggest that even if the first amino acids of the mature protein do not contribute to its overall structural stability, they condition the kinetic parameters of the import reaction. Besides, the distance between the transit peptide and the mature protein core may be modulating the import rate at which the chloroplast incorporates this protein from the cytosol.     

Domains of a Transit Sequence Required for in Vivo Import in Arabidopsis Chloroplasts

Nuclear-encoded precursors of chloroplast proteins are synthesized with an amino-terminal cleavable transit sequence, which contains the information for chloroplastic targeting. To determine which regions of the transit sequence are most important for its function, the chloroplast uptake and processing of a full-length ferredoxin precursor and four mutants with deletions in adjacent regions of the transit sequence were analyzed. Arabidopsis was used as an experimental system for both in vitro and in vivo import. The full-length wild-type precursor translocated efficiently into isolated Arabidopsis chloroplasts, and upon expression in transgenic Arabidopsis plants only mature-sized protein was detected, which was localized inside the chloroplast. None of the deletion mutants was imported in vitro. By analyzing transgenic plants, more subtle effects on import were observed. The most N-terminal deletion resulted in a fully defective transit sequence. Two deletions in the middle region of the transit sequence allowed translocation into the chloroplast, although with reduced efficiencies. One deletion in this region strongly reduced mature protein accumulation in older plants. The most C-terminal deletion was translocated but resulted in defective processing. These results allow the dissection of the transit sequence into separate functional regions and give an in vivo basis for a domain-like structure of the ferredoxin transit sequence.     

N-terminal domain of the dual-targeted pea glutathione reductase signal peptide controls organellar targeting efficiency

Import of nuclear-encoded proteins into mitochondria and chloroplasts is generally organelle specific and its specificity depends on the N-terminal signal peptide. Yet, a group of proteins known as dual-targeted proteins have a targeting peptide capable of leading the mature protein to both organelles. We have investigated the domain structure of the dual-targeted pea glutathione reductase (GR) signal peptide by using N-terminal truncations. A mutant of the GR precursor (pGR) starting with the second methionine residue of the targeting peptide, pGRdelta2-4, directed import into both organelles, negating the possibility that dual import was controlled by the nature of the N terminus. The deletion of the 30 N-terminal residues (pGRdelta2-30) inhibited import efficiency into chloroplasts substantially and almost completely into mitochondria, whereas the removal of only 16 N-terminal amino acid residues (pGRdelta2-16) resulted in the strongly stimulated mitochondrial import without significantly affecting chloroplast import. Furthermore, N-terminal truncations of the signal peptide (pGRdelta2-16 and pGRdelta2-30) greatly stimulated the mitochondrial processing activity measured with the isolated processing peptidase. These results suggest a domain structure for the dual-targeting peptide of pGR and the existence of domains controlling organellar import efficiency therein.