Chloroplast transport of a ribulose bisphosphate carboxylase small subunit-5-enolpyruvyl 3-phosphoshikimate synthase chimeric protein requires part of the mature small subunit in addition to the transit peptide

Ribulose bisphosphate carboxylase small subunit protein is synthesized in the cytoplasm as a precursor and transported into the chloroplast where the amino-terminal portion, the transit peptide, is removed proteolytically. To obtain chloroplast delivery of the 43-kDa 5-enolpyruvyl 3-phosphoshikimate (EPSP) synthase of Salmonella typhimurium, we constructed fusion proteins between the bacterial EPSP synthase and the ribulose bisphosphate carboxylase small subunit. A fusion protein consisting of the transit peptide fused to the EPSP synthase was not transported in vitro or in vivo into chloroplasts. A second fusion protein consisting of the transit peptide and 24 amino acids of the mature small subunit fused to the EPSP synthase was transported both in vitro and in vivo into chloroplasts. It was processed into two polypeptides of 46 and 47 kDa, respectively. This heterogeneity in processing was not caused by the presence of the aroA start codon, since its removal resulted in the same pattern. Substituting 24 different amino acids for the 24 amino acids of the mature small subunit resulted in a fusion protein that was not transported into the chloroplast. It was concluded that a portion of the mature small subunit was needed for efficient chloroplast delivery.     

The importance of the transit peptide and the transported protein for protein import into chloroplasts

Summary We compared the transport in vitro of fusion proteins of neomycin phosphotransferase II (NPTII) with either the transit peptide of the small subunit (SSU) of ribulose-1,5-bisphosphate carboxylase/oxygenase or the transit peptide and the 23 aminoterminal amino acids of the mature small subunit. The results showed that the transit peptide is sufficient for import of NPTII. However, transport of the fusion protein consisting of the transit peptide linked directly to NPTII was very inefficient. In contrast, the fusion protein containing a part of the mature SSU was imported with an efficiency comparable to that of the authentic SSU precursor. We conclude from these results that other features of the precursor protein in addition to the transit peptide are important for transport into chloroplasts. In order to identify functional regions in the transit peptide, we analyzed the transport of mutant fusion proteins. We found that the transport of fusion proteins with large deletions in the aminoterminal, or central part was drastically reduced. In contrast, duplication of a part of the transit peptide led to a marked increase in transport.     

Targeting of protein to chloroplasts in transgenic tobacco by fusion to mutated transit peptide

Summary Transport of foreign proteins into chloroplasts was studied in a transgenic plant expressing two different fusion proteins, the transit peptide (TP) of ribulose-bisphosphate carboxylase small subunit (SS) fused to neomycin phosphotransferase (TP-NPT II) and, the same transit peptide plus the amino-terminal 23 amino acids of mature SS linked to NPT II. The second fusion protein (TP-SS-NPT II) was found in isolated chloroplasts but accumulated to a lesser degree than the first (TP-NPT II). This finding does not support the hypothesis that the highly conserved amino acid sequence surrounding the cleavage site between the transit peptide (TP) and mature SS is required for efficient transport. This cleavage region shows a markedly higher conservation than either the mature protein or the TP sequences in SS genes from different plant species. Evidence is presented indicating that the transport of the TP-SS-NPT II precursor is diminished as a result of competition between the rate of its uptake and the rate of its degradation by cytosolic proteases. In an attempt to identify further regions in the TP involved in transport and processing, we designed derivatives of both the TP-SS-NPT II and TP-NPT II precursors. A derivative of TP-SS-NPT II lacking the amino acids at the processing site was expressed in plants and was shown to be transported and processed. A derivative of TP-NPT II comprising the first 41 amino acids (out of 57) of the transit peptide linked to NPT II was also expressed in plants. This protein was not imported into the organelles; however a significant amount of partially processed fusion protein was found to be attached to the outer membrane of the chloroplast.     

A novel chlorophyll a/b binding (Cab) protein gene from petunia which encodes the lower molecular weight Cab precursor protein.

The 16 petunia Cab genes which have been characterized are all closely related at the nucleotide sequence level and they encode Cab precursor polypeptides which are similar in sequence and length. Here we describe a novel petunia Cab gene which encodes a unique Cab precursor protein. This protein is a member of the smallest class of Cab precursor proteins for which no gene has previously been assigned in petunia or any other species. The features of this Cab precursor protein are that it is shorter by 2-3 amino acids than the formerly characterized Cab precursors, its transit peptide sequence is unrelated, and the mature polypeptide is significantly diverged at the functionally important N terminus from other petunia Cab proteins. Gene structure also discriminates this gene which is the only intron containing Cab gene in petunia genomic DNA.     

A strong protein unfolding activity is associated with the binding of precursor chloroplast proteins to chloroplast envelopes

Protein conformational changes related to transport into chloroplasts have been studied. Two chimaeric proteins carrying the transit peptide of either ferredoxin or plastocyanin linked to the mouse cytosolic enzyme dihydrofolate reductase (EC 1.5.1.3.) were employed. In contrast to observations in mitochondria, we found in chloroplasts that transport of a purified ferredoxin-dihydrofolate reductase fusion protein is not blocked by the presence of methotrexate, a folate analogue that stabilizes the structural conformation of dihydrofolate reductase. It is shown that transport competence of this protein in the presence of methotrexate is not a consequence of alteration of the folding characteristics or methotrexate binding properties of dihydrofolate reductase by fusion to the ferredoxin transit peptide. Binding of dihydrofolate reductase fusion proteins to chloroplast envelopes is not inhibited by low temperature and it is only partially diminished by methotrexate. It is demonstrated that the dihydrofolate reductase fusion proteins unfold, despite the presence of methotrexate, on binding to the chloroplast envelopes. We propose the existence of a strong protein unfolding activity associated to the chloroplast envelopes.     

Secondary structure and folding of a functional chloroplast precursor protein.

Ferredoxin is a chloroplast stroma protein which is cytosolically synthesized as a precursor with an amino-terminal extension called the transit sequence that is needed for the post-translational uptake by the chloroplast. To characterize the secondary and tertiary structure elements, the full precursor, the holo- and apo- (without iron-sulfur cluster) forms of the mature protein, and the chemically synthesized transit peptide were obtained and analyzed separately. Circular dichroism, tryptophan fluorescence quenching, and protease accessibility experiments indicate that the precursor has a low content of defined secondary structure and resembles unfolded proteins; these properties are due to both the mature part and the transit sequence. This result provides an explanation for the lack of cytosolic factor requirement of this protein for import. In an import competition assay, the isolated transit peptide had an affinity for the chloroplasts comparable to the full precursor. Interestingly and of possible importance to the import process, the transit peptide has conformational flexibility as it adopts alternative secondary structures in different environments.     

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.     

Regions in the transit peptide of SSU essential for transport into chloroplasts

Summary Deletion mutations, 3–19 amino acids in size, were introduced into the transit peptide (57 amino acids) of a small subunit (SSU) of ribulose-1,5-bisphosphate carboxylase/oxygenase from pea. Transport of the authentic small subunit precursor (pSSU) and of the mutant pSSUs by isolated chloroplasts of pea was examined. We show that the transit peptide contains two different, separated functional regions. A deletion mutation in the central region of the transit peptide, a region purported to be important for function, barely affected transport. Changes in the amino-terminal region of the transit peptide drastically reduced transport. Processing of mutants affected in either the amino-terminal or central portion of the transit peptide appeared normal. A deletion mutation at the carboxy-terminus of the transit peptide interfered with both transport and processing. From the aberrant processing we suggest that pSSU is matured in more than one step, and that the maturation signal is located within the carboxy-terminal 16 amino acids. The methionine residue at the evolutionarily conserved cleavage site (cysteine-methionine) between the transit peptide and the mature protein is not essential for processing.     

Isolation and characterisation of the cDNA encoding a glycosylated accessory protein of pea chloroplast DNA polymerase.

The cDNA encoding p43, a DNA binding protein from pea chloroplasts (ct) that binds to cognate DNA polymerase and stimulates the polymerase activity, has been cloned and characterised. The characteristic sequence motifs of hydroxyproline-rich glyco-proteins (HRGP) are present in the cDNA corres-ponding to the N-terminal domain of the mature p43. The protein was found to be highly O-arabinosylated. Chemically deglycosylated p43 (i.e. p29) retains its binding to both DNA and pea ct-DNA polymerase but fails to stimulate the DNA polymerase activity. The mature p43 is synthesised as a pre-p43 protein containing a 59 amino acid long transit peptide which undergoes stromal cleavage as evidenced from the post-translational in vitro import of the precursor protein into the isolated intact pea chloroplasts. Surprisingly, p43 is found only in pea chloroplasts. The unique features present in the cloned cDNA indicate that p43 is a novel member of the HRGP family of proteins. Besides p43, no other DNA-polymerase accessory protein with O-glycosylation has been reported yet.     

Isolation, characterization and evolutionary relatedness of three members from the soybean multigene family encoding chlorophyll a/b binding proteins.

The soybean light-harvesting complex II (LHC II) was composed of one major and three minor chlorophyll a/b (Cab) binding proteins. This study demonstrated that the soybean genome contained at least 11 genes that code for these Cab proteins. Three members of the soybean Cab gene family were characterized. Cab 3 coded for a 25.7 kD mature apoprotein with a 32 amino acid transit peptide. Comparisons with previously published Cab protein sequences indicated that Cab 3 coded for the major Cab protein of LHC II. Cab 2 coded for a novel Cab protein with an apparent molecular weight of 24.6 kD. Cab 2 retained a high degree of similarity with Cab 3, but distinguished itself from previously reported minor photosystem II type II Cab genes and products. Finally, Cab 1 was determined to be a pseudogene that had two deletions relative to Cab 2 and Cab 3.     

In vivo import experiments in protoplasts reveal the importance of the overall context but not specific amino acid residues of the transit peptide during import into chloroplasts

The N-terminal transit peptide of chloroplast proteins is necessary and sufficient to direct proteins to the chloroplasts. However, the requirement of the transit peptide of chloroplast proteins is not fully understood. In this study we investigated the requirement of a transit peptide at the level of amino acid sequence using an in vivo targeting approach. Targeting experiments with green fluorescent protein (GFP) fusion proteins containing varying lengths of the N-terminal region of the small subunit of rubisco complex (RbcS) revealed that at least 73 amino acid residues of the N-terminal region is required to direct GFP to the chloroplasts without affecting the efficiency. Even a small deletion from the C- or N-termini of the minimal length of the transit peptide results in strong inhibition of targeting. Also, a small internal deletion within the minimal transit peptide strongly affected targeting of GFP fusion proteins. However, when we replaced one or two amino acid residues of the transit peptide with corresponding numbers of alanine residues sequentially, all the mutants were imported into chloroplasts with 80 to 100% efficiency. Together these results suggest that the overall context of amino acid sequence, but not any specific amino acid residue, of the transit peptide is critical for targeting to the chloroplasts.     

Isolation and characterization of a cDNA from Cuphea lanceolata encoding a beta-ketoacyl-ACP reductase.

Summary A cDNA encoding -ketoacyl-ACP reductase (EC 1.1.1.100), an integral part of the fatty acid synthase type II, was cloned fromCuphea lanceolata. This cDNA of 1276 by codes for a polypeptide of 320 amino acids with 63 N-terminal residues presumably representing a transit peptide and 257 residues corresponding to the mature protein of 27 kDa. The encoded protein shows strong homology with the amino-terminal sequence and two tryptic peptides from avocado mesocarp -ketoacyl-ACP reductase, and its total amino acid composition is highly similar to those of the -ketoacyl-ACP reductases of avocado and spinach. Amino acid sequence homologies to polyketide synthase, -ketoreductases and short-chain alcohol dehydrogenases are discussed. An engineered fusion protein lacking most of the transit peptide, which was produced inEscherichia coli, was isolated and proved to possess -ketoacyl-ACP reductase activity. Hybridization studies revealed that inC. lanceolata -ketoacyl-ACP reductase is encoded by a small family of at least two genes and that members of this family are expressed in roots, leaves, flowers and seeds.     

Current views on chloroplast protein import and hypotheses on the origin of the transport mechanism

Most chloroplastic proteins are synthesized as precursors in the cytosol prior to their transport into chloroplasts. These precursors are generally synthesized in a form that is larger than the mature form found inside chloroplasts. The extra amino acids, called transit peptides, are present at the amino terminus. The transit peptide is necessary and sufficient to recognize the chloroplast and induce movement of the attached protein across the envelope membranes. In this review, we discuss the primary and secondary structure of transit peptides, describe what is known about the import process, and present some hypotheses on the evolutionary origin of the import mechanism.Abbreviations DHFR dihydrofolate reductase - EPSP synthase 5-enolpyrovylshikimate-3-phosphate synthase; hsp heat-shock protein - LHCP II light-harvesting chlorophylla/b binding protein - OEE 16, 23, and 33 the 16-, 23-, and 33-kDa proteins of the oxygen-evolving complex - pr precursor - rubisco ribulose-1,5-bisphosphate carboxylase/oxygenase - SS rubisco small subunit     

Nuclear-encoded tobacco chloroplast ribosomal protein L24. Protein identification, sequence analysis of cDNAs encoding its cytoplasmic precursor, and mRNA and genomic DNA analysis.

Using a Nicotiana tabacum leaf cDNA library in the expression vector lambda gt11, two cDNAs encoding the full-length precursor polypeptide (M(r) 20,696) of tobacco chloroplast ribosomal protein L24 were identified and sequenced. These cDNAs encode a mature protein of 146 amino acids (M(r) 16,418) with a transit peptide of 41 amino acids (M(r) 4,278). The mature tobacco L24 protein has 78, 65, 45, and 35% sequence identity with ribosomal proteins L24 of pea, spinach, Bacillus subtilis, and Escherichia coli, respectively. The transit peptide of tobacco L24 is 54 and 57% identical with that of L24 chloroplast ribosomal proteins of pea and spinach, respectively. An expressed beta-galactosidase:L24 fusion protein, bound to nitrocellulose filters, was used as affinity matrix to purify monospecific antibody to L24 protein. Using this monospecific antibody protein L24 was identified among high performance liquid chromatography (HPLC)-purified tobacco chloroplast ribosome 50 S subunit proteins. The predicted amino terminus of the mature L24 protein was confirmed by partial sequencing of the HPLC-purified L24 protein. Northern blot analysis revealed a single mRNA band (0.85-0.90 kilobase) corresponding in size to full-length L24 cDNA. The presence of multiple genes for L24 is suggested by Southern blot hybridization and characterization of two cDNAs for L24 which only differ in their 3'-noncoding sequences.     

Structural and kinetic properties of adenylyl sulfate reductase from Catharanthus roseus cell cultures

A cDNA encoding a plant-type APS reductase was isolated from an axenic cell suspension culture of Catharanthus roseus (Genbank/EMBL-databank accession number U63784). The open reading frame of 1392 bp (termed par) encoded for a protein (Mr=51394) consisting of a N-terminal transit peptide, a PAPS reductase-like core and a C-terminal extension with homology to the thioredoxin-like domain of protein disulfide isomerase. The APS reductase precursor was imported into pea chloroplasts in vitro and processed to give a mature protein of approximately 45 kDa. The homologous protein from pea chloroplast stroma was detected using anti:par polyclonal antibodies. To investigate the catalytical function of the different domains deleted par proteins were purified. ParDelta1 lacking the transit sequence liberated sulfite from APS (Km 2.5+/-0.23 microM) in vitro with glutathione (Km 3+/-0.64 mM) as reductant (Vmax 2.6+/-0.14 U mg-1, molecular activity 126 min-1). ParDelta2 lacking the transit sequence and C-terminal domain had to be reconstituted with exogenous thioredoxin as reductant (Km 15. 3+/-1.27 microM, Vmax 0.6+/-0.014 U mg-1). Glutaredoxin, GSH or DTT were ineffective substitutes. ParDelta1 (35.4%) and parDelta2 (21. 8%) both exhibited insulin reductase activity comparable to thioredoxin (100%). Protein disulfide isomerase activity was observed for parDelta1.     

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.     

Synthetic analogues of a transit peptide inhibit binding or translocation of chloroplastic precursor proteins

Although amino-terminal transit peptides of chloroplastic precursor proteins are known to be necessary and sufficient for import into chloroplasts, the mechanism by which they mediate this process is not understood. Another important question is whether different precursors share a common transport apparatus. We used 20-residue synthetic peptides corresponding to regions of the transit peptide of the precursor to the small subunit of ribulose bisphosphate carboxylase (prSS) as competitive inhibitors for the binding and translocation of precursor proteins into chloroplasts. Synthetic peptides with sequences corresponding to either end of the transit peptide had little to no effect on binding of prSS to chloroplasts, but significantly inhibited its translocation. Synthetic peptides corresponding to the central region of the transit peptide inhibited binding of prSS to chloroplasts. Each of the peptides inhibited binding or translocation of precursors to light-harvesting chlorophyll a/b protein, ferredoxin, and plastocyanin in the same manner and to a similar extent as prSS transport was inhibited. The results presented in this paper suggest that the central regions of the transit peptide of prSS mediate binding to the chloroplastic surface, whereas the ends of this transit peptide are more important for translocation across the envelope. Furthermore, all of the precursors tested appear to share components in the transport apparatus even though they are sorted to different chloroplastic compartments.