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.     

Requirement for three membrane-spanning alpha-helices in the post-translational insertion of a thylakoid membrane protein.

The insertion of a protein into a lipid bilayer usually involves a short signal sequence and can occur either during or after translation. A light-harvesting chlorophyll a/b-binding protein (LHCP) is synthesized in the cytoplasm of plant cells as a precursor and is post-translationally imported into chloroplasts where it subsequently inserts into the thylakoid membrane. Only mature LHCP is required for insertion into the thylakoid. To define which sequences of the mature protein are necessary and sufficient for thylakoid integration, fusion and deletion proteins and proteins with internal rearrangements were synthesized and incubated with isolated thylakoids and stroma. No evidence is found for the existence of a short signal sequence within LHCP, and, with the exception of the amino terminus and a short lumenal loop, the entire mature protein with consecutively ordered alpha-helices is required for insertion into thylakoid membranes. The addition of positive charges into stromal but not lumenal segments permits the insertion of mutant LHCPs into isolated thylakoids. Replacement of the LHCP transit peptide with the transit peptide from plastocyanin has no effect on LHCP insertion and does not restore insertion of the lumenal charge addition mutants.     

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 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.     

Information for targeting to the chloroplastic inner envelope membrane is contained in the mature region of the maize Bt1-encoded protein.

Based on the protein sequence deduced from a cDNA clone, it has been proposed that the maize bt1 locus encodes an amyloplast membrane metabolite translocator protein (Sullivan, T. D., Strelow, L. I., Illingworth, C. A., Phillips, R. L., and Nelson, O. E., Jr. (1991) Plant Cell 3, 1337-1348). The present work provides further evidence for this hypothesis by showing that the gene product of Bt1 could be imported into chloroplasts in vitro and processed to lower molecular weight mature proteins. More importantly, the imported mature proteins were localized to the inner envelope membrane, where metabolite translocators are located in plastids. In addition, the location of information for targeting to the inner membrane was investigated by constructing and analyzing the import of chimeric precursor proteins. A chimeric protein with the transit peptide of the precursor to the small subunit of ribulose-1,5-bisphosphate carboxylase fused to the mature region of the Bt1-encoded protein was targeted to the inner envelope membrane of chloroplasts. Moreover, a chimeric protein with the transit peptide of the Bt1-encoded protein fused to the mature protein of the light-harvesting chlorophyll a/b binding protein was targeted to the thylakoid. These results indicate that the transit peptide of the Bt1-encoded protein functions primarily as a stromal targeting sequence. The information for targeting to the chloroplastic inner envelope membrane is contained in the mature region of the protein.     

Protein Import into and Sorting inside the Chloroplast Are Independent Processes

Plastocyanin is a nuclear-encoded chloroplast thylakoid lumen protein that is synthesized in the cytoplasm with a large N-terminal extension (66 amino acids). Transport of plastocyanin involves two steps: import across the chloroplast envelope into the stroma, followed by transfer across the thylakoid membrane into the lumen. During transport the N-terminal extension is removed in two parts by two different processing proteases. In this study we examined the functions of the two cleaved parts, C1 and C2, in the transport pathway of plastocyanin. The results show that C1 mediates import into the chloroplast. C1 is sufficient to direct chloroplast import of mutant proteins that lack C2. It is also sufficient to direct import of a nonplastid protein and can be replaced functionally by the transit peptide of an imported stromal protein. C2 is a prerequisite for intraorganellar routing but is not required for chloroplast import. Deletions in C2 result in accumulation of intermediates in the stroma or on the outside of the thylakoids. The fact that C1 is functionally equivalent to a stromal-targeting transit peptide shows that plastocyanin is imported into the chloroplast by way of the same mechanism as stromal proteins, and that import into and routing inside the chloroplasts are independent processes.     

An Arabidopsis thaliana protein homologous to cyanobacterial high-light-inducible proteins

An Arabidopsis thaliana cDNA clone encoding a novel 110 amino acid thylakoid protein has been sequenced. The in vitro synthesized protein is taken up by intact chloroplasts, inserted into the thylakoid membrane and the transit peptide is cleaved off during this process. The mature protein is predicted to contain 69 amino acids, to form one membrane-spanning -helix and to have its N-terminus at the stromal side of the thylakoid membrane. The protein showed similarity to the LHC, ELIP and PsbS proteins of higher plants, but more pronounced to the high-light-inducible proteins (HLIPs) of cyanobacteria and red algae, to which no homologue previously has been detected in higher plants. As for HLIP and ELIP, high light increases the mRNA levels of the corresponding gene. Sequence comparisons indicate that the protein may bind chlorophyll and form dimers in the thylakoid membrane. The level of expression of the protein seems to be far lower than that of normal PSI and PSII subunits.     

The role of the transit peptide in the routing of precursors toward different chloroplast compartments

The role of the transit peptide in the routing of imported proteins inside the chloroplast was investigated with chimeric proteins in which the transit peptides for the nuclear-encoded ferredoxin and plastocyanin precursors were exchanged. Import and localization experiments with a reconstituted chloroplast system show that the ferredoxin transit peptide directs mature plastocyanin away from its correct location, the thylakoid lumen, to the stroma. With the plastocyanin transit peptide-mature ferredoxin chimera, a processing intermediate is arrested on its way to the lumen. We propose a two domain hypothesis for the plastocyanin transit peptide: the first domain functions in the chloroplast import process, whereas the second is responsible for transport across the thylakoid membrane. Thus, the transit peptide not only targets proteins to the chloroplast, but also is a major determinant in their subsequent localization within the organelle.     

Targeting a foreign protein to chloroplasts using fusions to the transit peptide of a chlorophyll a/b protein

We have constructed chimaeric genes consisting of sequences encoding the transit peptide and 4, 16, 24, 53 or 126 amino-terminal residues of the mature chlorophyll a/b binding (Cab) apoprotein fused to the Escherichia coli gene encoding beta-glucuronidase (GUS). These genes were introduced into tobacco plants and the fate of the fusion proteins they encode was analysed. Less than 1% of the total activity of fusion proteins containing the transit peptide and 4 (FP4) or 16 (FP16) amino-terminal amino acids of the mature Cab protein was associated with chloroplasts. Moreover, FP4 appears to be unprocessed. This is in striking contrast to fusion proteins containing the transit peptide and 24 (FP24), 53 (FP53) or 126 (FP126) amino-terminal residues of the mature Cab polypeptide. Approximately 98%, 96% or 75%, respectively, of the total activity of these fusion proteins was associated with purified intact chloroplasts, and protease protection experiments showed that of this, approximately 98%, 87% or 50%, respectively, was located within this organelle. Furthermore, both FP24 and FP53 appear to be processed. However, less than 10% of the activity of those fusion proteins translocated into chloroplasts was associated with thylakoid membranes.     

Bacterial twin-arginine signal peptide-dependent protein translocation pathway: evolution and mechanism

The recently identified bacterial Tat pathway is capable of exporting proteins with a peculiar twin-arginine signal peptide in folded conformation independently of the Sec machinery. It is structurally and mechanistically similar to the delta pH-dependent pathway used for importing chloroplast proteins into the thylakoid. The tat genes are not ubiquitously present and are absent from half of the completely sequenced bacterial genomes. The presence of the tat genes seems to correlate with genome size and with the presence of important enzymes with a twin-arginine signal peptide. A minimal Tat system requires a copy of tatA and a copy of tatC. The composition and gene order of a tat locus are generally conserved within the same taxonomy group but vary considerably to other groups, which would exclude an acquisition of the Tat system by recent horizontal gene transfer. The tat genes are also found in the genomes of chloroplasts and plant mitochondria but are absent from animal mitochondrial genomes. The topology of evolution trees suggests a bacterial origin of the Tat system. In general, the twin-arginine signal peptide is capable of targeting any passenger protein to the Tat pathway. However, a structural signal carried by the mature part of a passenger protein can override targeting information in a signal peptide under certain circumstances. Tat systems show a substrate-Tat component specificity and a species specificity. The pore size of the Tat channel is estimated as being between 5 and 9 nm. Operational models of the Tat system are proposed.     

The chlorophyll a/b-binding protein inserts into the thylakoids independent of its cognate transit peptide

In order to determine if the cognate transit peptide of the light-harvesting chlorophyll a/b-binding protein (LHCP) is essential for LHCP import into the chloroplast and proper localization to the thylakoids, it was replaced with the transit peptide of the small subunit (S) of ribulose-1,5-bisphosphate carboxylase/oxygenase, a stromal protein. Wheat LHCP and S genes were fused to make a chimeric gene coding for the hybrid precursor, which was synthesized in vitro and incubated with purified pea chloroplasts. My results show that LHCP is translocated into chloroplasts by the S transit peptide. The hybrid precursor was processed; and most importantly, mature LHCP did not remain in the stroma, but was inserted into thylakoid membranes, where it normally functions. Density gradient centrifugation showed no LHCP in the envelope fraction. Hence, the transit peptide of LHCP is not required for intraorganellar routing, and LHCP itself contains an internal signal for localization to the correct membrane compartment.     

Protein targeting towards the thylakoid lumen of chloroplasts: proper localization of fusion proteins is only observed in vivo.

Routeing of fusion proteins to the thylakoid lumen of the chloroplast was compared in vitro and in vivo. The Escherichia coli protein beta-lactamase was used as a passenger to study this intraorganellar sorting process. The first step, translocation of beta-lactamase into the chloroplast stroma, occurs properly both in vitro and in vivo and is dependent on the presence of a transit peptide in the protein construct. The second step, targeting towards the thylakoid lumen, is more complicated as was also observed previously when other passenger proteins were used. In vitro, the presence of a thylakoid transfer domain is not enough for routeing and proper processing. Only when the complete thylakoid lumen precursor plastocyanin was fused to beta-lactamase was the fusion protein processed adequately, but routeing was still incomplete. However, in vivo, the information present in the thylakoid transfer domain was the only requirement for proper transport towards the thylakoid lumen. These data show that in vivo, the only requirement for targeting of passenger proteins towards the thylakoid lumen is the presence of a transit peptide and a thylakoid transfer domain. Furthermore, we demonstrate that the in vitro import system does not necessarily reflect the in vivo situation with respect to intraorganellar sorting.     

The transit peptide of CP29 thylakoid protein in Chlamydomonas reinhardtii is not removed but undergoes acetylation and phosphorylation

The surface-exposed peptides were cleaved by trypsin from the photosynthetic thylakoid membranes isolated from the green alga Chlamydomonas reinhardtii. Two phosphorylated peptides, enriched from the peptide mixture and sequenced by nanospray quadrupole time-of-flight mass spectrometry, revealed overlapping sequences corresponding to the N-terminus of a nuclear-encoded chlorophyll a/b-binding protein CP29. In contrast to all known nuclear-encoded thylakoid proteins, the transit peptide in the mature algal CP29 was not removed but processed by methionine excision, N-terminal acetylation and phosphorylation on threonine 6. The importance of this phosphorylation site is proposed as the reason of the unique transit peptide retention.     

A protein oxidase catalysing disulfide bond formation is localized to the chloroplast thylakoids

In chloroplasts, thiol/disulfide-redox-regulated proteins have been linked to numerous metabolic pathways. However, the biochemical system for disulfide bond formation in chloroplasts remains undetermined. In the present study, we characterized an oxidoreductase, AtVKOR-DsbA, encoded by the gene At4g35760 as a potential disulfide bond oxidant in Arabidopsis. The gene product contains two distinct domains: an integral membrane domain homologous to the catalytic subunit of mammalian vitamin K epoxide reductase (VKOR) and a soluble DsbA-like domain. Transient expression of green fluorescent protein fusion in Arabidopsis protoplasts indicated that AtVKOR-DsbA is located in the chloroplast. The first 45 amino acids from the N-terminus were found to act as a transit peptide targeting the protein to the chloroplast. An immunoblot assay of chloroplast fractions revealed that AtVKOR-DsbA was localized in the thylakoid. A motility complementation assay showed that the full-length of AtVKOR-DsbA, if lacking its transit peptide, could catalyze the formation of disulfide bonds. Among the 10 cysteine residues present in the mature protein, eight cysteines (four in the AtVKOR domain and four in the AtDsbA domain) were found to be essential for promoting disulfide bond formation. The topological arrangement of AtVKOR-DsbA was assayed using alkaline phosphatase sandwich fusions. From these results, we developed a possible topology model of AtVKOR-DsbA in chloroplasts. We propose that the integral membrane domain of AtVKOR-DsbA contains four transmembrane helices, and that both termini and the cysteines involved in catalyzing the formation of disulfide bonds face the oxidative thylakoid lumen. These studies may help to resolve some of the issues surrounding the structure and function of AtVKOR-DsbA in Arabidopsis chloroplasts.     

Downregulation of ClpR2 leads to reduced accumulation of the ClpPRS protease complex and defects in chloroplast biogenesis in Arabidopsis

Plastids contain tetradecameric Clp protease core complexes, with five ClpP Ser-type proteases, four nonproteolytic ClpR, and two associated ClpS proteins. Accumulation of total ClpPRS complex decreased twofold to threefold in an Arabidopsis thaliana T-DNA insertion mutant in CLPR2 designated clpr2-1. Differential stable isotope labeling of the ClpPRS complex with iTRAQ revealed a fivefold reduction in assembled ClpR2 accumulation and twofold to fivefold reductions in the other subunits. A ClpR2:(his)(6) fusion protein that incorporated into the chloroplast ClpPRS complex fully complemented clpr2-1. The reduced accumulation of the ClpPRS protease complex led to a pale-green phenotype with delayed shoot development, smaller chloroplasts, decreased thylakoid accumulation, and increased plastoglobule accumulation. Stromal ClpC1 and 2 were both recruited to the thylakoid surface in clpr2-1. The thylakoid membrane of clpr2-1 showed increased carotenoid content, partial inactivation of photosystem II, and upregulated thylakoid proteases and stromal chaperones, suggesting an imbalance in chloroplast protein homeostasis and a well-coordinated network of proteolysis and chaperone activities. Interestingly, a subpopulation of PsaF and several light-harvesting complex II proteins accumulated in the thylakoid with unprocessed chloroplast transit peptides. We conclude that ClpR2 cannot be functionally replaced by other ClpP/R homologues and that the ClpPRS complex is central to chloroplast biogenesis, thylakoid protein homeostasis, and plant development.     

Import of Modified Dl Protein and its Assembly into Photosystem II by Isolated Chloroplasts

A portion of the rbcS gene that encoded the transit peptideand 20 amino acid residues of the N-tenninal region of the smallsubunit of ribulosebisphosphate carb-oxylase/oxygenase was fusedto the 5' end of the psbA gene which encodes the Dl proteinof PSII reaction center. The chimeric gene was expressed invitro as a 42-kDa protein, which was imported into chloroplastsisolated from pea leaves. The imported protein was processedsuch that the transit peptide was lost in the stroma, the resultantprotein was translocated into thylakoid membranes, and the C-ter-minalpeptide was then removed to yield a mature protein with an N-terminalextension originated from the small sub-unit. The mature proteinappeared to be assembled into the PSII core complex, resemblingthe native Dl protein in terms of protein structure and topologywithin the membrane. Our observations indicate that the structureof the precursor to the Dl protein includes information forthe proper assembly of the protein into the PSII core complex. (Received September 10, 1996; Revision received December 14, 1996. )     

Chloroplast YidC homolog Albino3 can functionally complement the bacterial YidC depletion strain and promote membrane insertion of both bacterial and chloroplast thylakoid proteins

A new component of the bacterial translocation machinery, YidC, has been identified that specializes in the integration of membrane proteins. YidC is homologous to the mitochondrial Oxa1p and the chloroplast Alb3, which functions in a novel pathway for the insertion of membrane proteins from the mitochondrial matrix and chloroplast stroma, respectively. We find that Alb3 can functionally complement the Escherichia coli YidC depletion strain and promote the membrane insertion of the M13 procoat and leader peptidase that were previously shown to depend on the bacterial YidC for membrane translocation. In addition, the chloroplast Alb3 that is expressed in bacteria is essential for the insertion of chloroplast cpSecE protein into the bacterial inner membrane. Surprisingly, Alb3 is not required for the insertion of cpSecE into the thylakoid membrane. These results underscore the importance of Oxa1p homologs for membrane protein insertion in bacteria and demonstrate that the requirement for Oxa1p homologs is different in the bacterial and thylakoid membrane systems.     

What is the role of the transit peptide in thylakoid integration of the light-harvesting chlorophyll a/b protein?

Whereas it is widely accepted that the transit peptide of the precursor for the light-harvesting chlorophyll a/b protein (preLHCP) is responsible for targeting this polypeptide to chloroplasts, the signals which govern its intraorganellar targeting appears to be transit peptide-mediated for plastocyanin (Smeekins, S., Bauerle, C., Hageman, J., Keegstra, K., and Weisbeek, P. (1986) Cell 46, 365-375) and several other nuclear-encoded, thylakoid luminal proteins. To determine whether a similar mechanism operates for LHCP (an integral thylakoid protein), we have used oligonucleotide-directed mutagenesis to delete the proposed transit sequence from a petunia precursor of this polypeptide. Intact preLHCP and the deletion mutant product have been expressed in vitro, and their abilities to integrate into purified thylakoids have been compared. We have found that both polypeptides insert into thylakoids correctly, provided the latter are supplemented with a membrane-free stromal extract and Mg.ATP. Our results clearly demonstrate that whereas the transit peptide is required for transport into chloroplasts, thylakoid integration of preLHCP is determined by mature portions of the polypeptide. In addition, we note that transit peptide removal has little effect on the apparent solubility of the in vitro translation products.     

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.