Processing of a wheat light-harvesting chlorophyll a/b protein precursor by a soluble enzyme from higher plant chloroplasts

Expression of CphB- and CphE-type cyanophycinases in cyanophycin-producing tobacco and comparison of their ability to degrade cyanophycin in plant and plant extracts

Increasing the arginine (Arg) content in plants used as feed or food is of interest, since the supplementation of food with conditionally essential Arg has been shown to have nutritional benefits. An increase was achieved by the expression of the Arg-rich bacterial storage component, cyanophycin (CGP), in the chloroplast of transgenic plants. CGP is stable in plants and its degradation into β-aspartic acid (Asp)-Arg dipeptides, is solely catalyzed by bacterial cyanophycinases (CGPase). Dipeptides can be absorbed by animals even more efficiently than free amino acids (Matthews and Adibi 1976; Wenzel et al. 2001). The simultaneous production of CGP and CGPase in plants could be a source of β-Asp-Arg dipeptides if CGP degradation can be prevented in planta or if dipeptides are stable in the plants. We have shown for the first time that it is possible to co-express CGP and CGPase in the same plant without substrate degradation in planta by transient expression of the cyanobacterial CGPase CPHB (either in the plastid or cytosol), and the non-cyanobacterial CGPase CPHE (cytosol) in CGP-producing Nicotiana tabacum plants. We compared their ability to degrade CGP in planta and in crude plant extracts. No CGP degradation appeared prior to cell homogenization independent of the CGPase produced. In crude plant extracts, only cytosolic CPHE led to a fast degradation of CGP. CPHE also showed higher stability and in vitro activity compared to both CPHB variants. This work is the next step to increase Arg in forage plants using a stable, Arg-rich storage protein.

Once upon a Time - Chloroplast Protein Import Research from Infancy to Future Challenges

Protein import into chloroplasts has been a focus of research for several decades. The first publications dealing with this fascinating topic appeared in the 1970s. From the initial realization that many plastid proteins are being encoded for in the nucleus and require transport into their target organelle to the identification of import components in the cytosol, chloroplast envelopes, and stroma, as well as elucidation of some mechanistic details, more fascinating aspects are still being unraveled. With this overview, we present a survey of the beginnings of chloroplast protein import research, the first steps on this winding road, and end with a glimpse into the future.

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.

Reconstitution of protein targeting to the inner envelope membrane of chloroplasts

The chloroplast envelope plays critical roles in the synthesis and regulated transport of key metabolites, including intermediates in photosynthesis and lipid metabolism. Despite this importance, the biogenesis of the envelope membranes has not been investigated in detail. To identify the determinants of protein targeting to the inner envelope membrane (IM), we investigated the targeting of the nucleus-encoded integral IM protein, atTic40. We found that pre-atTic40 is imported into chloroplasts and processed to an intermediate size (int-atTic40) before insertion into the IM. Int-atTic40 is soluble and inserts into the IM from the internal stromal compartment. We also show that atTic40 and a second IM protein, atTic110, can target and insert into isolated IM vesicles in vitro. Collectively, our experiments are consistent with a "postimport" mechanism in which the IM proteins are first imported from the cytoplasm and subsequently inserted into the IM from the stroma.

Proteomics of Chlamydomonas reinhardtii light-harvesting proteins

With the recent development of techniques for analyzing transmembrane thylakoid proteins by two-dimensional gel electrophoresis, systematic approaches for proteomic analyses of membrane proteins became feasible. In this study, we established detailed two-dimensional protein maps of Chlamydomonas reinhardtii light-harvesting proteins (Lhca and Lhcb) by extensive tandem mass spectrometric analysis. We predicted eight distinct Lhcb proteins. Although the major Lhcb proteins were highly similar, we identified peptides which were unique for specific lhcbm gene products. Interestingly, lhcbm6 gene products were resolved as multiple spots with different masses and isoelectric points. Gene tagging experiments confirmed the presence of differentially N-terminally processed Lhcbm6 proteins. The mass spectrometric data also revealed differentially N-terminally processed forms of Lhcbm3 and phosphorylation of a threonine residue in the N terminus. The N-terminal processing of Lhcbm3 leads to the removal of the phosphorylation site, indicating a potential novel regulatory mechanism. At least nine different lhca-related gene products were predicted by comparison of the mass spectrometric data against Chlamydomonas expressed sequence tag and genomic databases, demonstrating the extensive variability of the C. reinhardtii Lhca antenna system. Out of these nine, three were identified for the first time at the protein level. This proteomic study demonstrates the complexity of the light-harvesting proteins at the protein level in C. reinhardtii and will be an important basis of future functional studies addressing this diversity.

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-beta-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.

Isoforms of photosystem II antenna proteins in different plant species revealed by liquid chromatography-electrospray ionization mass spectrometry

The high selectivity offered by reversed-phase high-performance liquid chromatography on-line coupled to electrospray ionization mass spectrometry has been utilized to characterize the major and minor light-harvesting proteins of photosystem II (Lhcb). Isomeric forms of the proteins, revealed either on the basis of different hydrophobicity enabling their chromatographic separation or on the basis of different molecular masses identified within one single chromatographic peak, were readily identified in a number of monocot and dicot species. The presence of several Lhcb1 isoforms (preferably in dicots) can explain the tendency of dicot Lhcb1 to form trimeric aggregates. The Lhcb1 molecular masses ranged from 24,680 to 25,014 among different species, whereas within the same species, the isoforms differed by 14-280 mass units. All Lhcb1 proteins appear to be highly conserved among different species such that they belong to a single gene group that has several different gene family members. In all species examined, the number of isoforms corresponded more or less to the genes cloned previously. Two isoforms of Lhcb3 were found in petunia and tomato. For Lhcb6, the most divergent of all light-harvesting proteins, the greatest number of isoforms was found in petunia, tobacco, tomato, and rice. Lhcb2, Lhcb4, and Lhcb5 were present in only one form. The isoforms are assumed to play an important role in the adaptation of plants to environmental changes.

Towards functional proteomics of membrane protein complexes: analysis of thylakoid membranes from Chlamydomonas reinhardtii

Functional proteomics of membrane proteins is an important tool for the understanding of protein networks in biological membranes but structural studies on this part of the proteome are limited. In this study we undertook such an approach to analyse photosynthetic thylakoid membranes isolated from wild-type and mutant strains of Chlamydomonas reinhardtii. Thylakoid membrane proteins were separated by high-resolution two-dimensional gel electrophoresis (2-DE) and analysed by immuno-blotting and mass spectrometry for the presence of membrane-spanning proteins. Our data show that light-harvesting complex proteins (LHCP), that cross the membrane with three transmembrane domains, can be separated using this method. We have identified more than 30 different LHCP spots on our gels. Mass spectrometric analysis of 2-DE separated Lhcb1 indicates that this major LHCII protein can associate with the thylakoid membrane with part of its putative transit sequence. Separation of isolated photosystem I (PSI) complexes by 2-DE revealed the presence of 18 LHCI protein spots. The use of two peptide-specific antibodies directed against LHCI subunits supports the interpretation that some of these spots represent products arising from differential processing and post-translational modifications. In addition our data indicate that the reaction centre subunit of PSI, PsaA, that possesses 11 transmembrane domains, can be separated by 2-DE. Comparison between 2-DE maps from thylakoid membrane proteins isolated from a PSI-deficient (Deltaycf4) and a crd1 mutant, which is conditionally reduced in PSI and LHCI under copper-deficiency, showed the presence of most of the LHCI spots in the former but their absence in the latter. Our data demonstrate that (i) hydrophobic membrane proteins like the LHCPs can be faithfully separated by 2-DE, and (ii) that high-resolution 2-DE facilitates the comparative analysis of membrane protein complexes in wild-type and mutants cells.

Diatom fucoxanthin chlorophyll a/c-binding protein (FCP) and land plant light-harvesting proteins use a similar pathway for thylakoid membrane Insertion

The light-harvesting proteins in plastids of different lineages including algae and land plants represent a superfamily of chlorophyll-binding proteins that seem to be phylogenetically related, although some of the light-harvesting complex (LHC) proteins bind different carotenoids. LHCs can be divided into chlorophyll a/b-binding proteins found in green algae, euglenoids, and higher plants and into chlorophyll a/c-binding proteins of various algal taxa. LHC proteins from diatoms are named fucoxanthin-chlorophyll a/c-binding proteins (FCP). In contrast to chlorophyll a/b-binding proteins, there is no information so far about the way FCPs integrate into thylakoid membranes. The diatom FCP preproteins have a bipartite presequence that is necessary to enable transport into the four membrane-bound diatom plastids, but similar to chlorophyll a/b-binding proteins there is apparently no presequence present for targeting to the thylakoid membrane. By establishing an in vitro import assay for diatom thylakoids, we demonstrated that thylakoid integration of diatom FCP depends on the presence of stromal factors and GTP. This indicates that a pathway involving signal recognition particles (SRP) is involved in membrane integration just as shown for LHCs in higher plants. We also demonstrate integration of diatom FCP into thylakoids of higher plants and vice versa SRP-dependent targeting of LHCs from pea and Arabidopsis into diatom thylakoids. The similar SRP-dependent modes of thylakoid integration of land plant LHCs and FCPs support recent analyses indicating a common origin of chlorophyll a/b- and a/c-binding proteins.

Stromal processing peptidase binds transit peptides and initiates their ATP-dependent turnover in chloroplasts

A stromal processing peptidase (SPP) cleaves a broad range of precursors targeted to the chloroplast, yielding proteins for numerous biosynthetic pathways in different compartments. SPP contains a signature zinc-binding motif, His-X-X-Glu-His, that places it in a metallopeptidase family which includes the mitochondrial processing peptidase. Here, we have investigated the mechanism of cleavage by SPP, a late, yet key event in the import pathway. Recombinant SPP removed the transit peptide from a variety of precursors in a single endoproteolytic step. Whereas the mature protein was immediately released, the transit peptide remained bound to SPP. SPP converted the transit peptide to a subfragment form that it no longer recognized. We conclude that SPP contains a specific binding site for the transit peptide and additional proteolysis by SPP triggers its release. A stable interaction between SPP and an intact transit peptide was directly demonstrated using a newly developed binding assay. Unlike recombinant SPP, a chloroplast extract rapidly degraded both the transit peptide and subfragment. A new degradative activity, distinguishable from SPP, was identified that is ATP- and metal-dependent. Our results indicate a regulated sequence of events as SPP functions during precursor import, and demonstrate a previously unrecognized ATP-requirement for transit peptide turnover.

Multiple light-harvesting II polypeptides from maize mesophyll chloroplasts are distinct gene products

The major light-harvesting complex of photosystem II in higher plants is known as LHCII. It is composed of a number of chlorophyll-binding proteins sharing epitopes with each other. The number of apoproteins resolved by fully denaturing sodium dodecylsulfate polyacrylamide gel electrophoresis varies in different species. In order to know if this heterogeneity is caused by the expression of a number of homologous genes or if it is the product of post-translational modifications, we have resolved the six major apoproteins of Zea mays LHCII. Each protein is purified to homogeneity, subjected to direct protein sequencing and the sequences compared with those deduced from lhcb genes in maize and other organisms. All of the six proteins are distinct gene products, since they show differences in their primary structure. Three apoproteins are identified as products of type I lhcb genes and one each as type II and type III gene products. A sixth protein does not fit the requirements for any of the lhcb genes so far cloned and is therefore probably the product of an lhcb gene type not yet described. Our results clearly show that the major source of LHCII protein heterogeneity is the expression of many lhcb genes. Fractionation of maize LHCII by non-denaturing flat-bed isoelectric focusing resolves at least five major isoforms showing distinct differences in their polypeptide composition and also differing in their spectroscopic properties, thus suggesting that individual Lhcb gene products have distinct pigment-binding properties.

Purification and properties of a novel chloroplast stromal peptidase. Processing of polyphenol oxidase and other imported precursors

Polyphenol oxidases (PPOs) are nuclear-encoded chloroplast proteins that are targeted to the thylakoid lumen by a bipartite presequence. The N-terminal part of this sequence is removed by a stromal processing peptidase (SPP), and the resulting intermediate is translocated across the thylakoid and processed to the mature protein. A 4800-fold-purified SPP processed a PPO precursor (pPPO) at a site identical to that occurring in organelle. The in vitro product of SPP action on pPPO was further processed and translocated by thylakoids. This SPP processed other precursors but was inactive toward those of light-harvesting chlorophyll binding proteins. The enzyme appeared to be a metalloendopeptidase, like previously reported SPPs. However, it differed in substrate specificity, apparent size, and, most significantly, cleavage site of pPPO. Whereas the processing sites of lumen proteins determined so far were relatively distant from the hydrophobic core of the thylakoid targeting domain, pPPO was cleaved immediately before this domain. Cleavage removed the twin arginine motif characteristic of thylakoid targeting domains of lumen proteins, which are translocated by the DeltapH-dependent pathway. The possible significance of these observations to PPO translocation mechanism is discussed. It is suggested that several SPPs may exist in chloroplasts with preferences for different subsets of precursors.

A chloroplast processing enzyme functions as the general stromal processing peptidase

A highly specific stromal processing activity is thought to cleave a large diversity of precursors targeted to the chloroplast, removing an N-terminal transit peptide. The identity of this key component of the import machinery has not been unequivocally established. We have previously characterized a chloroplast processing enzyme (CPE) that cleaves the precursor of the light-harvesting chlorophyll a/b binding protein of photosystem II (LHCPII). Here we report the overexpression of active CPE in Escherichia coli. Examination of the recombinant enzyme in vitro revealed that it cleaves not only preLHCPII, but also the precursors for an array of proteins essential for different reactions and destined for different compartments of the organelle. CPE also processes its own precursor in trans. Neither the recombinant CPE nor the native CPE of chloroplasts process a preLHCPII mutant with an altered cleavage site demonstrating that both forms of the enzyme are sensitive to the same structural modification of the substrate. The transit peptide of the precursor of ferredoxin is released by a single cleavage event and found intact after processing by recombinant CPE and a chloroplast extract as well. These results provide the first direct demonstration that CPE is the general stromal processing peptidase that acts as an endopeptidase. Significantly, recombinant CPE cleaves in the absence of other chloroplast proteins, and this activity depends on metal cations, such as zinc.

Subcellular location of the tetrapyrrole synthesis enzyme porphobilinogen deaminase in higher plants: an immunological investigation

A recombinant plasmid, pArab8, harbouring the cDNA encoding the mature form of the tetrapyrrole synthesis enzyme porphobilinogen deaminase (EC 4.3.1.8; also known as hydroxymethylbilane synthase) from Arabidopsis thaliana (L.) Heynh. has been constructed, and used to transform Escherichia coli. The porphobilinogen deaminase protein from Arabidopsis was overexpressed in this strain, and purified to homogeneity (3000-fold) with a yield of 20%. Antibodies were raised against the purified plant enzyme, and used in Western blot analysis, immunoprecipitation of enzyme activity and immuno-gold electron microscopy. The results indicate that the enzyme is confined to plastids in both leaves and roots. The implications of this finding for plant tetrapyrrole synthesis are discussed.

A chloroplast processing enzyme involved in precursor maturation shares a zinc-binding motif with a recently recognized family of metalloendopeptidases

Nuclear-encoded proteins targeted to the chloroplast are typically synthesized with N-terminal transit peptides which are proteolytically removed upon import. Structurally related proteins of 145 and 143 kDa copurify with a soluble chloroplast processing enzyme (CPE) that cleaves the precursor for the major light-harvesting chlorophyll a/b binding protein and have been implicated in the maturation of the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase and acyl carrier protein. The 145- and 143-kDa proteins have not been found as a heterodimer and thus may represent functionally independent isoforms encoded by separate genes. Here we describe the primary structure of a 140-kDa polypeptide encoded by cDNAs isolated by using antibodies raised against the 145/143-kDa doublet. The 140-kDa polypeptide contains a transit peptide, and strikingly, a His-Xaa-Xaa-Glu-His zinc-binding motif that is conserved in a recently recognized family of metalloendopeptidases, which includes Escherichia coli protease III, insulin-degrading enzyme, and subunit beta of the mitochondrial processing peptidase. Identity of 25-30%, concentrated near the N terminus of the 140-kDa polypeptide, is found with these proteases. Expression of CPE in leaves is not light dependent. Indeed, transcripts are present in dark-grown plants, and the 145/143-kDa doublet and proteolytic activity are both found in etioplasts, as well as in root plastids. Thus, CPE appears to be a necessary component of the import machinery in photosynthetic and nonphotosynthetic tissues, and it may function as a general stromal processing peptidase in plastids.

Polyamines in chloroplasts: identification of their glutamyl and acetyl derivatives

Incubation of chloroplasts of Helianthus tuberosus with labelled putrescine and/or spermidine and proteolytic digestion of their trichloroacetate-soluble and -insoluble proteins revealed the presence of N-(gamma-glutamyl)-putrescine, N1,N4-bis-(gamma-glutamyl)-putrescine and N1,N8-bis-(gamma-glutamyl)spermidine. This finding may be regarded as unequivocal proof of the presence of transglutaminase activity in chloroplasts. In addition, the recovery of spermidine or putrescine and acetylspermidine from chloroplasts incubated with [3H]putrescine or [3H]spermidine respectively indicates the existence of biosynthetic and oxidative pathways. These results suggest that polyamines may have an important function in chloroplasts both in their free form and by covalently binding to proteins.

Nucleoside diphosphate kinase from pea chloroplasts: purification, cDNA cloning and import into chloroplasts

Nucleoside diphosphate kinase (NDPK; EC 2.7.4.6) was enriched 1900-fold from purified pea (Pisum sativum L. cv. Golf.) chloroplasts. The active enzyme preparation contained two polypeptides of apparent molecular weight 18.5 kDa and 17.4 kDa. Both proteins were enzymatically active and were recognized by an antiserum raised against NDPK from spinach chloroplasts, suggesting the existence of two isoforms in pea chloroplasts. The N-terminal protein sequence data were obtained for both polypeptides and compared with the nucleotide sequence of a cDNA clone isolated from a pea cDNA library. The analysis revealed that the two NDPK forms are encoded for by one mRNA, indicating that the lower-molecular-weight form could represent a proteolytic breakdown product of the 18.5-kDa NDPK. The pea chloroplastic NDPK is made as a larger precursor protein which is imported into chloroplasts. The NDPK precursor is then processed by the stromal processing peptidase to yield the 18.5-kDa form.

Acyl carrier protein (ACP) import into chloroplasts. Covalent modification by a stromal holoACP synthase is stimulated by exogenously added CoA and inhibited by adenosine 3',5'-bisphosphate

During the import of the precursor for the acyl carrier protein (ACP) into chloroplasts, apoACP is converted to holoACP by the attachment of a phosphopantetheine group transferred from coenzyme A (CoA) by a chloroplast holoACP synthase [Fernandez, M. and Lamppa, G. (1990) Acyl carrier protein import into chloroplasts does not require the phosphopantetheine: evidence for a chloroplast holoACP synthase, Plant Cell 2, 195-206]. Here it is shown that exogenous addition of CoA to intact chloroplasts in the import assay stimulates the conversion of apoACP to holoACP. If adenosine 3',5'-bisphosphate [Ado(3',5')P2], the byproduct of the transfer reaction, was also included the extent of conversion was greatly reduced. CoA has its effect after ACP precursor (pre-ACP) import and proteolytic removal of the transit peptide, thus indicating that the chloroplast holoACP synthase resides in the stroma where fatty acid synthase is found. When Ado(3',5')P2 was added alone to the import assay, it inhibited the synthesis of holoACP. Inhibition of the conversion of apo- to holoACP with Ado(3',5')P2 made it possible to examine whether the holoform of preACP could be imported into chloroplasts. Pre-apoACP was synthesized in Escherichia coli and shown to be competent for import in an ATP- and temperature-dependent manner. A partially purified chloroplast holoACP synthase converted 60-90% of the pre-apoACP to pre-holoACP. Pre-holoACP incubated with chloroplasts in the presence of Ado(3',5')P2 yielded > 60% holoACP, whereas the control reaction with pre-apoACP gave primarily apoACP. Hence the phosphopantetheine prosthetic group of ACP does not block precursor movement through the translocation apparatus of the chloroplast envelope.

Biogenesis of a photosystem I light-harvesting complex. Evidence for a membrane intermediate

CAB-7p is a chlorophyll a/b binding protein of photosystem I (PSI). It is found in light-harvesting complex I 680 (LHCI-680), one of the chlorophyll complexes produced by detergent solubilization of PSI. Two types of evidence are presented to indicate that assembly of CAB-7p into PSI proceeds through a membrane intermediate. First, when CAB-7p is briefly imported into chloroplasts or isolated thylakoids, we initially observe a fast-migrating membrane form of CAB-7p that is subsequently converted into PSI. The conversion of the fast-migrating form into PSI does not require stroma or ATP. Second, trypsin treatment of thylakoids containing radiolabeled CAB-7p indicates that there are at least two membrane forms of the mature 23-kD protein. The predominant form is completely resistant to proteolysis; a second form of the protein is cleaved by trypsin into 12- and 7-kD polypeptides. We interpret this to mean that the intermediate is a cleavable form that becomes protease resistant during assembly. This notion is supported by the observation that CAB-7p in LHCI-680 is largely cleaved by trypsin into 12- and 7-kD polypeptides, whereas CAB-7p in isolated PSI particles is trypsin resistant. In vitro, we generated a mutant form of CAB-7p, CAB-7/BgI2p, that was able to integrate into thylakoid membranes but was unable to assemble into PSI. The membrane form of CAB-7/BgI2p, like LHCI-680, was predominantly cleaved by trypsin into 12- and 7-kD fragments. We suggest that the mutant protein is arrested at an intermediate stage in the assembly pathway of PSI. Based on its mobility in nondenaturing gels and its susceptibility to protease cleavage, we suggest that the intermediate form is LHCI-680. We propose the following distinct stages in the biogenesis of LHCI: (a) apoprotein is integrated into the thylakoid, (b) chlorophyll is rapidly bound to apoprotein forming LHCI-680, and (c) LHCI-680 assembles into the native PSI complex.

Processing of the Precursors for the Light-Harvesting Chlorophyll-Binding Proteins of Photosystem II and Photosystem I during Import and in an Organelle-Free Assay

We have investigated whether the precursors for the light-harvesting chlorophyll a/b binding proteins (LHCP) of photosystems II and I (PSII and PSI) are cleavable substrates in an organelle-free reaction, and have compared the products with those obtained during in vitro import into chloroplasts. Representatives from the tomato (Lycopersicon esculentum) LHCP family were analyzed. The precursor for LHCP type I of PSII (pLHCPII-1), encoded by the tomato gene Cab3C, was cleaved at only one site in the organelle-free assay, but two sites were recognized during import, analogous to our earlier results with a wheat precursor for LHCPII-1. The relative abundance of the two peptides produced was investigated during import of pLHCPII-1 into chloroplasts isolated from plants greened for 2 or 24 hours. In contrast to pLHCPII-1, the precursors for LHCP type II and III of PSI were cleaved in both assays, giving rise to a single peptide. The precursor for LHCP type I of PSI, encoded by gene Cab6A, yielded two peptides of 23.5 and 21.5 kilodaltons during import, whereas in the organelle-free assay only the 23.5 kilodalton peptide was found. N-terminal sequence analysis of this radiolabeled peptide has tentatively identified the site cleaved in the organelle-free assay between met40 and ser41 of the precursor.

Correlation of apoproteins with the genes of the major chlorophyll a/b binding protein of photosystem II in Arabidopsis thaliana. Confirmation for the presence of a third member of the LHC IIb gene family

The major light-harvesting complex in higher plants is LHC IIb. The LHC IIb of Arabidopsis thaliana contains 2 pigment-binding apoproteins of 28 and 25 kDa. To determine the relationship between them and the LHC IIb gene family members, each protein was purified to homogeneity, subjected to direct protein sequencing, and the sequences compared with those deduced from LHC IIb genes in this organism. The 28 kDa protein is the product of Type I LHC IIb genes. The 25 kDa LHC IIb component is distinctly different from the 28 kDa LHC IIb protein, and is more closely related to the type III LHC IIb gene product of barley. Type III gene products lack the first 9-11 residues found in proteins of the Type I and II genes, a region that contains a phosphorylatable threonine residue. The lack of the N-terminal residues explains why this LHC IIb apoprotein has never been seen to be phosphorylated, and partly or wholly why it is smaller. The implication of the missing N-terminus on uptake of LHC II precursor proteins into the plastid and of the relative organization of the LHC IIb subunits in the PS II antenna is discussed.

Determinants for cleavage of the chlorophyll a/b binding protein precursor: a requirement for a basic residue that is not universal for chloroplast imported proteins

We demonstrate that the precursor of the major light-harvesting chlorophyll a/b binding protein (LHCP of Photosystem II), encoded by a Type I gene, contains distinct determinants for processing at two sites during in vitro import into the chloroplast. Using precursors from both pea and wheat, it is shown that primary site processing, and release of a approximately 26-kD peptide, depends on an amino-proximal basic residue. Substitution of an arginine at position -4 resulted in an 80% reduction in processing, with the concomitant accumulation of a high molecular weight intermediate. Cleavage occurred normally when arginine was changed to lysine. The hypothesis that a basic residue is a general requirement for transit peptide removal was tested. We find that the precursors for the small subunit of Rubisco and Rubisco activase do not require a basic residue within seven amino acids of the cleavage site for maturation. In the wheat LHCP precursor, determinants for efficient cleavage at a secondary site were identified carboxy to the primary site, beyond what is traditionally called the transit peptide, within the sequence ala-lys-ala-lys (residues 38-41). Introduction of this sequence into the pea precursor, which has the residues thr-thr-lys-lys in the corresponding position, converted it to a substrate with an efficiently recognized secondary site. Our results indicate that two different forms of LHCP can be produced with distinct NH2-termini by selective cleavage of a single precursor polypeptide.

Soluble Chloroplast Enzyme Cleaves preLHCP Made in Escherichia coli to a Mature Form Lacking a Basic N-Terminal Domain

We have investigated the specificity of a chloroplast soluble processing enzyme that cleaves the precursor of the major light-harvesting chlorophyll a/b binding protein (LHCP). The precursor of LHCP (preLHCP) was synthesized in Escherichia coli and recovered from inclusion-like bodies. It was found to be a substrate for proteolytic cleavage by the soluble enzyme in an organelle-free reaction, yielding a 25 kilodalton peptide. This peptide co-migrated during sodium dodecyl sulfate-polyacrylamide gel electrophoresis with the smaller of the forms (25 and 26 kilodalton) produced when either the E. coli-synthesized precursor, or preLHCP made in a reticulocyte lysate, was imported into chloroplasts. N-Terminal sequence analysis of the E. coli-generated precursor showed that it lacked an N-terminal methionine. N-Terminal sequencing of the 25 kilodalton peptide produced in the organelle-free reaction indicated that processing occurred between residues 40 and 41, removing a basic domain (RKTAAK) thought to be at the N-terminus of all LHCP molecules of type I associated with photosystem II. To determine if the soluble enzyme involved also cleaves other precursor polypeptides, or is specific to preLHCP, it was partially purified, and the precursors for Rubisco small subunit, plastocyanin, Rubisco activase, heat shock protein 21, and acyl carrier protein were tested as substrates. All of these precursors were cleaved by the same chromatographic peak of activity that processes preLHCP in the organelle-free reaction.

On some of the in organello processes involved in the biogenesis of chlorophyll-protein complexes

The biogenesis and assembly of chlorophyll-protein complexes consist of many steps. These are initiated with the transcription and translation of the different polypeptide components constituting the complexes. For the nuclear-encoded subunits the synthesis takes place in the cytoplasm, and they are synthesized as precursors, which are later imported into the chloroplast. Within the organelle, the precursors are inserted into the thylakoid membranes, as well as being processed to their mature forms. The different nuclear- and chloroplast-encoded subunits assemble together, and bind the pigments and other cofactors to form the active pigmented-complex. In the present article, we discuss only the in organello processes of the biogenesis. We describe the pathways taken by two nuclear-encoded thylakoid proteins, the precursor of the main light-harvesting chlorophyll-protein of photosystem II (pLHCP) and the precursor of photosystem I subunit II (pre subunit II). These polypeptide subunits, that are located in two different photosynthetic complexes, differ from each other. While pLHCP is an integral membrane protein, which binds pigments, photosystem I-subunit II is a peripheral membrane protein, located on the stromal side of the thylakoids, and is not predicted to span it. The differences and the common features of the in organello biogenesis pathways of these two proteins are discussed.

Early events in the import/assembly pathway of an integral thylakoid protein

The light-harvesting chlorophyll a/b protein (LHCP) is nuclear-encoded and must traverse the chloroplast envelope before becoming integrally assembled into thylakoid membranes. Previous studies implicated a soluble stromal form of LHCP in the assembly pathway, but relied upon assays in which the thylakoid insertion step was intentionally impaired [Cline, K., Fulsom, D. R. and Viitanen, P. V. (1989) J. Biol. Chem. 264, 14225-14232]. Here we have developed a rapid-stopping procedure, based upon the use of HgCl2, to analyze early events of the uninhibited assembly process. With this approach, we have found that proper assembly of LHCP into thylakoids lags considerably behind trans-envelope translocation. During the first few minutes of import, two distinct populations of mature-size LHCP accumulate within the chloroplast. One is the aforementioned soluble stromal intermediate, while the other is a partially (or improperly) assembled thylakoid species. Consistent with precursor/product relationships, both species reach peak levels at a time when virtually none of the imported molecules are correctly assembled. These results confirm and extend our previous interpretation, that upon import, preLHCP is rapidly processed to its mature form, giving rise to a soluble stromal intermediate. They further suggest that the stromal intermediate initially inserts into the thylakoid bilayer in a partially assembled form, which eventually becomes properly assembled into the light-harvesting complex.

The rapidly phosphorylated 25 kDa polypeptide of the light- harvesting complex of photosystem II is encoded by the type 2 cab-II genes

The main light-harvesting complex of Photosystem II (LHC II) in higher plants consists of two sub-populations. The 'inner' pool consists only of a 27 kDa polypeptide, whereas in the 'outer' pool both the 27 kDa and a 25 kDa polypeptide are found. We purified the 25 and the 27 kDa LHC II polypeptides from Scots pine and 25 kDa LHC II polypeptide from spinach. Protein sequencing after cleavage with endoproteinase Lys-C showed that the 25 kDa polypeptide is encoded by the Type 2 cab-II genes and the 27 kDa polypeptide by the Type I cab-II genes. A fatty acid was not covalently attached to the peptides assembled into the pigment-protein complex. Our results show that the different polypeptides seen on a gel are different gene products, and not the result of different processing.

Properties of a Chloroplast Enzyme that Cleaves the Chlorophyll a/b Binding Protein Precursor : Optimization of an Organelle-Free Reaction

The major light-harvesting chlorophyll a/b binding protein (LHCP) of higher plant chloroplasts is nuclear-encoded, synthesized as a precursor, and processed upon import. We have previously (GK Lamppa, M Abad [1987] J Cell Biol 105: 2641-2648) identified a soluble enzyme that cleaves the LHCP precursor (pLHCP). In this study, we describe the conditions for optimal recovery of the processing activity and provide evidence that the N terminus of pLHCP is indeed cleaved, removing the transit peptide. Two pLHCP deletions were made from a cloned pLHCP gene removing 13 and 21 amino acids, respectively, from the carboxy terminus of the protein. After organelle-free processing, the cleavage products showed a shift in mobility during SDS-PAGE proportional to the size of the precursor truncations, as predicted for N-terminal processing. Unexpectedly, a third truncated precursor lacking 91 residues of the C-terminus was not cleaved although the transit peptide domain was intact, suggesting that this deletion disrupted conformational features of the precursor necessary for processing. The pLHCP processing enzyme is inhibited by 2 millimolar EDTA and the metal chelator 1, 10 phenanthroline at 0.4 millimolar, while being inhibited by EGTA only at high concentrations and insensitive to iodoacetate. Optimal processing occurs at pH 8 to 9, and 26 degrees C. Gel filtration chromatography shows that the pLHCP processing enzyme has an apparent molecular weight of about 240,000. The identical column fractions that process pLHCP also convert the precursor of the small subunit of ribulose-1,5-bisphosphate carboxylase to its mature form.

Recent developments in chloroplast protein transport

Most proteins located in chloroplasts are encoded by nuclear genes, synthesized in the cytoplasm, and transported into the organelle. The study of protein uptake by chloroplasts has greatly expanded over the past few years. The increased activity in this field is due, in part, to the application of recombinant DNA methodology to the analysis of protein translocation. Added interest has also been gained by the realization that the transport mechanisms that mediate protein uptake by chloroplasts, mitochondria and the endoplasmic reticulum display certain characteristics in common. These include amino terminal sequences that target proteins to particular organelles, a transport process that is mechanistically independent from the events of translation, and an ATP-requiring transport step that is thought to involve partial unfolding of the protein to be translocated. In this review we examine recent studies on the binding of precursors to the chloroplast surface, the energy-dependent uptake of proteins into the stroma, and the targeting of proteins to the thylakoid lumen. These aspects of protein transport into chloroplasts are discussed in the context of recent studies on protein uptake by mitochondria.