Preproteins of chloroplast envelope inner membrane contain targeting information for receptor-dependent import into fungal mitochondria

Ferroportin 3 is a dual-targeted mitochondrial/chloroplast iron exporter necessary for iron homeostasis in Arabidopsis

Mitochondria and chloroplasts are organelles with high iron demand that are particularly susceptible to iron-induced oxidative stress. Despite the necessity of strict iron regulation in these organelles, much remains unknown about mitochondrial and chloroplast iron transport in plants. Here, we propose that Arabidopsis ferroportin 3 (FPN3) is an iron exporter that is dual-targeted to mitochondria and chloroplasts. FPN3 is expressed in shoots, regardless of iron conditions, but its transcripts accumulate under iron deficiency in roots. fpn3 mutants cannot grow as well as the wild type under iron-deficient conditions and their shoot iron levels are lower compared with the wild type. Analyses of iron homeostasis gene expression in fpn3 mutants and inductively coupled plasma mass spectrometry (ICP-MS) measurements show that iron levels in the mitochondria and chloroplasts are increased relative to the wild type, consistent with the proposed role of FPN3 as a mitochondrial/plastid iron exporter. In iron-deficient fpn3 mutants, abnormal mitochondrial ultrastructure was observed, whereas chloroplast ultrastructure was not affected, implying that FPN3 plays a critical role in the mitochondria. Overall, our study suggests that FPN3 is essential for optimal iron homeostasis.

Protein import into plant mitochondria: signals, machinery, processing, and regulation

The majority of more than 1000 proteins present in mitochondria are imported from nuclear-encoded, cytosolically synthesized precursor proteins. This impressive feat of transport and sorting is achieved by the combined action of targeting signals on mitochondrial proteins and the mitochondrial protein import apparatus. The mitochondrial protein import apparatus is composed of a number of multi-subunit protein complexes that recognize, translocate, and assemble mitochondrial proteins into functional complexes. While the core subunits involved in mitochondrial protein import are well conserved across wide phylogenetic gaps, the accessory subunits of these complexes differ in identity and/or function when plants are compared with Saccharomyces cerevisiae (yeast), the model system for mitochondrial protein import. These differences include distinct protein import receptors in plants, different mechanistic operation of the intermembrane protein import system, the location and activity of peptidases, the function of inner-membrane translocases in linking the outer and inner membrane, and the association/regulation of mitochondrial protein import complexes with components of the respiratory chain. Additionally, plant mitochondria share proteins with plastids, i.e. dual-targeted proteins. Also, the developmental and cell-specific nature of mitochondrial biogenesis is an aspect not observed in single-celled systems that is readily apparent in studies in plants. This means that plants provide a valuable model system to study the various regulatory processes associated with protein import and mitochondrial biogenesis.

Green targeting predictor and ambiguous targeting predictor 2: the pitfalls of plant protein targeting prediction and of transient protein expression in heterologous systems

The challenges of plant protein targeting prediction are the existence of dual subcellular targets and the bias of experimentally confirmed data towards few and mostly nonplant model species. To assess whether training with proteins from evolutionarily distant species has a negative impact on prediction accuracy, we developed the Green Targeting Predictor tool, which was trained with a species-specific data set for Physcomitrella patens. Its performance was compared with that of the same tool trained with a mixed data set. In addition, we updated the Ambiguous Targeting Predictor. We found that predictions deviated from in vivo observations predominantly for proteins diverging within the green lineage, as well as for dual targeted proteins. To evaluate the usefulness of heterologous expression systems, selected proteins were subjected to localization studies in P. patens, Arabidopsis thaliana and Nicotiana tabacum. Four out of six proteins that show dual targeting in the original plant system were located only in a single compartment in one or both heterologous systems. We conclude that targeting signals of divergent plant species exhibit differences, calling for custom in silico and in vivo approaches when aiming to unravel the actual distribution patterns of proteins within a plant cell.

Functional expression and characterisation of membrane transport proteins

Membrane transporters set the framework organising the complexity of plant metabolism in cells, tissues and organisms. Their substrate specificity and controlled activity in different cells is a crucial part for plant metabolism to run pathways in concert. Transport proteins catalyse the uptake and exchange of ions, substrates, intermediates, products and cofactors across membranes. Given the large number of metabolites, a wide spectrum of transporters is required. The vast majority of in silico annotated membrane transporters in plant genomes, however, has not yet been functionally characterised. Hence, to understand the metabolic network as a whole, it is important to understand how transporters connect and control the metabolic pathways of plant cells. Heterologous expression and in vitro activity studies of recombinant transport proteins have highly improved their functional analysis in the last two decades. This review provides a comprehensive overview of the recent advances in membrane protein expression and functional characterisation using various host systems and transport assays.

Chloroplast β-barrel proteins are assembled into the mitochondrial outer membrane in a process that depends on the TOM and TOB complexes

Membrane-embedded β-barrel proteins are found in the outer membranes (OM) of Gram-negative bacteria, mitochondria and chloroplasts. In eukaryotic cells, precursors of these proteins are synthesized in the cytosol and have to be sorted to their corresponding organelle. Currently, the signal that ensures their specific targeting to either mitochondria or chloroplasts is ill-defined. To address this issue, we studied targeting of the chloroplast β-barrel proteins Oep37 and Oep24. We found that both proteins can be integrated in vitro into isolated plant mitochondria. Furthermore, upon their expression in yeast cells Oep37 and Oep24 were exclusively located in the mitochondrial OM. Oep37 partially complemented the growth phenotype of yeast cells lacking Porin, the general metabolite transporter of this membrane. Similarly to mitochondrial β-barrel proteins, Oep37 and Oep24 expressed in yeast cells were assembled into the mitochondrial OM in a pathway dependent on the TOM and TOB complexes. Taken together, this study demonstrates that the central mitochondrial components that mediate the import of yeast β-barrel proteins can deal with precursors of chloroplast β-barrel proteins. This implies that the mitochondrial import machinery does not recognize signals that are unique to mitochondrial β-barrel proteins. Our results further suggest that dedicated targeting factors had to evolve in plant cells to prevent mis-sorting of chloroplast β-barrel proteins to mitochondria.

Mitochondrial and plastid evolution in eukaryotes: an outsiders' perspective

The eukaryotic organelles mitochondrion and plastid originated from eubacterial endosymbionts. Here we propose that, in both cases, prokaryote-to-organelle conversion was driven by the internalization of host-encoded factors progressing from the outer membrane of the endosymbionts towards the intermembrane space, inner membrane and finally the organelle interior. This was made possible by an outside-to-inside establishment in the endosymbionts of host-controlled protein-sorting components, which enabled the gradual integration of organelle functions into the nuclear genome. Such a convergent trajectory for mitochondrion and plastid establishment suggests a novel paradigm for organelle evolution that affects theories of eukaryogenesis.

Refining the definition of plant mitochondrial presequences through analysis of sorting signals, N-terminal modifications, and cleavage motifs

Mitochondrial protein import is a complex multistep process from synthesis of proteins in the cytosol, recognition by receptors on the organelle surface, to translocation across one or both mitochondrial membranes and assembly after removal of the targeting signal, referred to as a presequence. In plants, import has to further discriminate between mitochondria and chloroplasts. In this study, we determined the precise cleavage sites in the presequences for Arabidopsis (Arabidopsis thaliana) and rice (Oryza sativa) mitochondrial proteins using mass spectrometry by comparing the precursor sequences with experimental evidence of the amino-terminal peptide from mature proteins. We validated this method by assessments of false-positive rates and comparisons with previous available data using Edman degradation. In total, the cleavable presequences of 62 proteins from Arabidopsis and 52 proteins from rice mitochondria were determined. None of these proteins contained amino-terminal acetylation, in contrast to recent findings for chloroplast stromal proteins. Furthermore, the classical matrix glutamate dehydrogenase was detected with intact and amino-terminal acetylated sequences, indicating that it is imported into mitochondria without a cleavable targeting signal. Arabidopsis and rice mitochondrial presequences had similar isoelectric points, hydrophobicity, and the predicted ability to form an amphiphilic alpha-helix at the amino-terminal region of the presequence, but variations in length, amino acid composition, and cleavage motifs for mitochondrial processing peptidase were observed. A combination of lower hydrophobicity and start point of the amino-terminal alpha-helix in mitochondrial presequences in both Arabidopsis and rice distinguished them (98%) from Arabidopsis chloroplast stroma transit peptides. Both Arabidopsis and rice mitochondrial cleavage sites could be grouped into three classes, with conserved -3R (class II) and -2R (class I) or without any conserved (class III) arginines. Class II was dominant in both Arabidopsis and rice (55%-58%), but in rice sequences there was much less frequently a phenylalanine (F) in the -1 position of the cleavage site than in Arabidopsis sequences. Our data also suggest a novel cleavage motif of (F/Y) downward arrow(S/A) in plant class III sequences.

Efficient mitochondrial targeting relies on co-operation of multiple protein signals in plants

To date, the most prevalent model for transport of pre-proteins to plant mitochondria is based on the activity of an N-terminal extension serving as a targeting peptide. Whether the efficient delivery of proteins to mitochondria is based exclusively on the action of the N-terminal extension or also on that of other protein determinants has yet to be defined. A novel mechanism is reported here for the targeting of a plant protein, named MITS1, to mitochondria. It was found that MITS1 contains an N-terminal extension that is responsible for mitochondrial targeting. Functional dissection of this extension shows the existence of a cryptic signal for protein targeting to the secretory pathway. The first 11 amino acids of the N-terminal extension are necessary to overcome the activity of this signal sequence and target the protein to the mitochondria. These data suggest that co-operation of multiple determinants within the N-terminal extension of mitochondrial proteins may be necessary for efficient mitochondrial targeting. It was also established that the presence of a tryptophan residue toward the C-terminus of the protein is crucial for mitochondrial targeting, as mutation of this residue results in a redistribution of MITS1 to the endoplasmic reticulum and Golgi apparatus. These data suggest a novel targeting model whereby protein traffic to plant mitochondria is influenced by domains in the full-length protein as well as the N-terminal extension.

AtOSA1, a member of the Abc1-like family, as a new factor in cadmium and oxidative stress response

The analysis of gene expression in Arabidopsis (Arabidopsis thaliana) using cDNA microarrays and reverse transcription-polymerase chain reaction showed that AtOSA1 (A. thaliana oxidative stress-related Abc1-like protein) transcript levels are influenced by Cd2+ treatment. The comparison of protein sequences revealed that AtOSA1 belongs to the family of Abc1 proteins. Up to now, Abc1-like proteins have been identified in prokaryotes and in the mitochondria of eukaryotes. AtOSA1 is the first member of this family to be localized in the chloroplasts. However, despite sharing homology to the mitochondrial ABC1 of Saccharomyces cerevisiae, AtOSA1 was not able to complement yeast strains deleted in the endogenous ABC1 gene, thereby suggesting different function between AtOSA1 and the yeast ABC1. The atosa1-1 and atosa1-2 T-DNA insertion mutants were more affected than wild-type plants by Cd2+ and revealed an increased sensitivity toward oxidative stress (hydrogen peroxide) and high light. The mutants exhibited higher superoxide dismutase activities and differences in the expression of genes involved in the antioxidant pathway. In addition to the conserved Abc1 region in the AtOSA1 protein sequence, putative kinase domains were found. Protein kinase assays in gelo using myelin basic protein as a kinase substrate revealed that chloroplast envelope membrane fractions from the AtOSA1 mutant lacked a 70-kD phosphorylated protein compared to the wild type. Our data suggest that the chloroplast AtOSA1 protein is a new factor playing a role in the balance of oxidative stress.

Structure, topology and function of the translocase of the outer membrane of mitochondria

Proteins destined for the mitochondria required the evolution of specific and efficient molecular machinery for protein import. The subunits of the import translocases of the inner membrane (TIM) appear homologous and conserved amongst species, however the components of the translocase of the outer membrane (TOM) show extensive differences between species. Recently, bioinformatic and structural analysis of Tom20, an important receptor subunit of the TOM complex, suggests that this protein complex arose from different ancestors for plants compared to animals and fungi, but has subsequently converged to provide similar functions and analogous structures. Here we review the current knowledge of the TOM complex, the function and structure of the various subunits that make up this molecular machine.

Functional analysis of the Arabidopsis PHT4 family of intracellular phosphate transporters

The transport of phosphate (Pi) between subcellular compartments is central to metabolic regulation. Although some of the transporters involved in controlling the intracellular distribution of Pi have been identified in plants, others are predicted from genetic, biochemical and bioinformatics studies. Heterologous expression in yeast, and gene expression and localization in plants were used to characterize all six members of an Arabidopsis thaliana membrane transporter family designated here as PHT4. PHT4 proteins share similarity with SLC17/type I Pi transporters, a diverse group of animal proteins involved in the transport of Pi, organic anions and chloride. All of the PHT4 proteins mediate Pi transport in yeast with high specificity. Bioinformatic analysis and localization of PHT4-GFP fusion proteins indicate that five of the proteins are targeted to the plastid envelope, and the sixth resides in the Golgi apparatus. PHT4 genes are expressed in both roots and leaves, although two of the genes are expressed predominantly in leaves and one mostly in roots. These expression patterns, together with Pi transport activities and subcellular locations, suggest roles for PHT4 proteins in the transport of Pi between the cytosol and chloroplasts, heterotrophic plastids and the Golgi apparatus.

In vitro and in vivo methods to study protein import into plant mitochondria

Plant mitochondria contain about 1000 proteins, 90-99% of which in different plant species are nuclear encoded, synthesized on cytosolic polyribosomes, and imported into the organelle. Most of the nuclear-encoded proteins are synthesized as precursors containing an N-terminal extension called a presequence or targeting peptide that directs the protein to the mitochondria. Here we describe in vitro and in vivo methods to study mitochondrial protein import in plants. In vitro synthesized precursor proteins can be imported in vitro into isolated mitochondria (single organelle import). However, missorting of chloroplast precursors in vitro into isolated mitochondria has been observed. A novel dual import system for simultaneous import of proteins into isolated mitochondria and chloroplasts followed by reisolation of the organelles is superior over the single import system as it abolishes the mistargeting. Precursor proteins can also be imported into the mitochondria in vivo using an intact cellular system. In vivo approaches include import of transiently expressed fusion constructs containing a presequence or a full-length precursor protein fused to a reporter gene, most commonly the green fluorescence protein (GFP) in protoplasts or in an Agrobacterium-mediated system in intact tobacco leaves.

Structure, evolution, and expression of the two invertase gene families of rice

Invertases catalyze the irreversible hydrolysis of sucrose to glucose and fructose. Plants contain two unrelated families of these enzymes: acid forms that derive from periplasmic invertases of eubacteria and are found in cell wall and vacuole, and neutral/alkaline forms evolved from the cytosolic invertases of cyanobacteria. Genomes of rice (Oryza sativa) and thale cress (Arabidopsis thaliana) contain multiple genes encoding these two families. Here for rice we identify the member genes of a cell-wall group (designated OsCIN1-9), a vacuolar group (OsVIN1-2), and two ancient neutral/alkaline groups: alpha (OsNIN1-4) and beta (OsNIN5-8). In Arabidopsis these groups contain six, two, four and five members, respectively. It is believed that the vacuolar group evolved from the cell-wall group. We provide evidence that the N-terminal signal peptide that directs cell-wall invertases co-translationally into the endoplasmic reticulum for secretion was replaced in the vacuolar group by a sequence similar to the complex N-terminal motif that targets alkaline phosphatase post-translationally to the vacuolar membrane of yeast. Since the last common ancestor of Arabidopsis and rice, the two invertase families evolved equally rapidly via gene duplication and gene loss, but the acid invertase family underwent approximately 10 events of intron loss compared with a single event of intron gain in the neutral/alkaline invertase family. Transcripts were detected for all rice invertase genes except OsCIN9. The acid invertase genes showed greater spatial and temporal diversity of expression than the neutral/alkaline genes.

Multi-membrane-bound structures of Apicomplexa: I. the architecture of the Toxoplasma gondii apicoplast

Apicomplexan parasites carry a plastid-like organelle termed apicoplast. The previous documentation of four membranes bordering the Toxoplasma gondii apicoplast suggested a secondary endosymbiotic ancestry of this organelle. However, a four-membraned apicoplast wall could not be confirmed for all Apicomplexa including the malarial agents. The latter reportedly possesses a mostly tri-laminar plastid wall but also displays two multi-laminar wall partitions. Since these sectors apparently evolved from regional wall membrane infoldings, the malarial plastid could have lost one secondary wall membrane in the course of evolution. Such wall construction was however not unambiguously resolved. To examine whether the wall of the T. gondii apicoplast is comparably complex, serial ultra-thin sections of tachyzoites were analyzed. This investigation revealed a single pocket-like invagination within a four-laminar wall segment but also disclosed that four individual membranes do not surround the entire T. gondii apicoplast. Instead, this organelle possesses an extensive sector that is bordered by two membranes. Such heterogeneous wall construction could be explained if the inner two membranes of a formerly four-membraned endosymbiont are partially lost. However, our findings are more consistent with an essentially dual-membraned organelle that creates four-laminar wall sectors by expansive infoldings of its interior border. Given this architecture, the T. gondii apicoplast depicts a residual primary plastid not a secondary one as presently proposed.

A phosphate transporter from Medicago truncatula is expressed in the photosynthetic tissues of the plant and located in the chloroplast envelope

• Phosphate is essential for many cellular processes including the light reactions of photosynthesis. Photosynthesis results in the production of triose phosphates that are transported across the chloroplast envelope to the cytosol in counterexchange for phosphate. Until recently, members of the plastid phosphate transport family, which mediate the exchange of phosphate for phosphorylated compounds, were the only proteins known to transport phosphate into the chloroplast. • Here, we characterized a phosphate transporter, MtPHT2;1 of Medicago truncatula. Transient expression of an MtPHT2;1-GFP fusion protein indicates that MtPHT2;1 is located in the chloroplast envelope. • The phosphate transport activity of MtPHT2;1 was assayed in yeast where the protein mediates phosphate uptake with a Km for phosphate of 0.6 m m and a pH optimum of 3-4. • MtPHT2;1 is expressed in all the photosynthetic tissues of the plant and transcript levels are also influenced by light, development and phosphate status of the plant. The phosphate transport activity and location in the chloroplast envelope membrane suggest a role for MtPHT2;1 in phosphate transport into the chloroplast.

A novel in vitro system for simultaneous import of precursor proteins into mitochondria and chloroplasts

Most chloroplast and mitochondrial precursor proteins are targeted specifically to either chloroplasts or mitochondria. However, there is a group of proteins that are dual targeted to both organelles. We have developed a novel in vitro system for simultaneous import of precursor proteins into mitochondria and chloroplasts (dual import system). The mitochondrial precursor of alternative oxidase, AOX was specifically targeted only to mitochondria. The chloroplastic precursor of small subunit of pea ribulose bisphosphate carboxylase/oxygenase, Rubisco, was mistargeted to pea mitochondria in a single import system, but was imported only into chloroplasts in the dual import system. The dual targeted glutathione reductase GR precursor was targeted to both mitochondria and chloroplasts in both systems. The GR pre-sequence could support import of the mature Rubisco protein into mitochondria and chloroplasts in the single import system but only into chloroplasts in the dual import system. Although the GR pre-sequence could support import of the mature portion of the mitochondrial FAd subunit of the ATP synthase into mitochondria and chloroplasts, mature AOX protein was only imported into mitochondria under the control of the GR pre-sequence in both systems. These results show that the novel dual import system is superior to the single import system as it abolishes mistargeting of chloroplast precursors into pea mitochondria observed in a single organelle import system. The results clearly show that although the GR pre-sequence has dual targeting ability, this ability is dependent on the nature of the mature protein.

Maize seryl-tRNA synthetase: specificity of substrate recognition by the organellar enzyme

In our study of seryl-tRNA formation in maize, we investigated the enzymes involved in serylation. Only two dissimilar seryl-tRNA synthetase (SerRS) cDNA clones were identified in the Zea mays EST (expressed sequence tag) databases. One encodes a seryl-tRNA synthetase, which presumably functions in the organelles (SerZMm), while the other synthetase product is more similar to eukaryotic cytosolic counterparts (SerZMc). The expression of SerZMm in Saccharomyces cerevisiae resulted in complementation of mutant respiratory phenotype, caused by a disruption of the nuclear gene, presumably encoding yeast mitochondrial seryl-tRNA synthetase (SerSCm). Purified mature SerZMm displays tRNA-assisted serine activation and aminoacylates maize mitochondrial and chloroplast tRNA(Ser) transcripts with similar efficiencies, raising the possibility that only two isoforms of seryl-tRNA synthetase may be sufficient to catalyze seryl-tRNA(Ser) formation in three cellular compartments of Zea mays. Phylogenetic analysis suggests that SerZMm is of mitochondrial origin.

Dual targeting to mitochondria and chloroplasts

Plant cells contain two organelles originally derived from endosymbiotic bacteria: mitochondria and plastids. Their endosymbiotic origin explains why these organelles contain their own DNA, nonetheless only a few dozens of genes are actually encoded by these genomes. Many of the other genes originally present have been transferred to the nuclear genome of the host, the product of their expression being targeted back to the corresponding organelle. Although targeting of proteins to mitochondria and chloroplasts is generally highly specific, an increasing number of examples have been discovered where the same protein is imported into both organelles. The object of this review is to compare and discuss these examples in order to try and identify common features of dual-targeted proteins. The study helps throw some light on the factors determining organelle targeting specificity, and suggests that dual-targeted proteins may well be far more common than once thought.

Signals required for the import and processing of the alternative oxidase into mitochondria

The critical residues involved in targeting and processing of the soybean alternative oxidase to plant and animal mitochondria was investigated. Import of various site-directed mutants into soybean mitochondria indicated that positive residues throughout the length of the presequence were important for import, not just those in the predicted region of amphiphilicity. The position of the positive residues in the C-terminal end of the presequence was also important for import. Processing assays of the various constructs with purified spinach mitochondrial processing peptidase showed that all the -2-position mutants had a drastic effect on processing. In contrast to the import assay, the position of the positive residue could be changed for processing. Deletion mutants confirmed the site-directed mutagenesis data in that an amphiphilic alpha-helix was not the only determinant of mitochondrial import in this homologous plant system. Import of these constructs into rat liver mitochondria indicated that the degree of inhibition differed and that the predicted region of amphiphilic alpha-helix was more important with rat liver mitochondria. Processing with a rat liver matrix fraction showed little inhibition. These results are discussed with respect to targeting specificity in plant cells and highlight the need to carry out homologous studies and define the targeting requirements to plant mitochondria.

Potential dual targeting of an Arabidopsis archaebacterial-like histidyl-tRNA synthetase to mitochondria and chloroplasts

A cDNA clone encoding a histidyl-tRNA synthetase (HisRS) was characterized from Arabidopsis thaliana. The deduced amino acid sequence (AtHRS1) is surprisingly more similar to HisRSs from archaebacteria than those from eukaryotes and prokaryotes. AtHRS1 has an N-terminal extension with features characteristic of mitochondrial and chloroplast transit peptides. Transient expression assays in tobacco protoplasts clearly demonstrated efficient targeting of a fusion peptide consisting of the first 71 amino acids of AtHRS1 joined to jellyfish green fluorescent protein (GFP) to both mitochondria and chloroplasts. These observations suggest that the AtHisRS1 cDNA encodes both mitochondrial and chloroplast histidyl-tRNA synthetases.

Temporal regulation of in vitro import of precursor proteins into tobacco mitochondria

Protein import into isolated tobacco mitochondria was investigated using mitochondria from leaves harvested at different times of the day and night. Efficient import was only detected with mitochondria isolated from leaves harvested during the dark period of the growth cycle, only low levels of import were detected from leaves harvested during the light period. However, this temporal difference seen in import did not appear to be circadian in nature. This implies that the protein import process in mitochondria isolated from leaves is not constitutive. This has important implications for targeting specificity studies performed in transgenic plants, as unless the plants are tested at the time when import is occurring, the true in vivo targeting abilities of chimeric constructs will not be measured.

Different in vitro and in vivo targeting properties of the transit peptide of a chloroplast envelope inner membrane protein

The triose phosphate 3-phosphoglycerate phosphate translocator (TPT) is a chloroplast envelope inner membrane protein whose transit peptide has structural properties typical of a mitochondrial presequence. To study the TPT transit peptide in more detail, we constructed two chimeric genes encompassing the TPT transit peptide and either 5 or 23 amino-terminal residues of the mature TPT, both linked to the reporter chloramphenicol acetyltransferase (cat) gene. The precursors were synthesized in vitro and translocated to and processed in purified plant mitochondria. However, this import was not specific since both precursors were also imported into isolated chloroplasts. To extend this analysis in vivo, the chimeric genes were introduced into tobacco by genetic transformation. Analysis of CAT distribution in subcellular fractions of transgenic plants did not confirm the data obtained in vitro. With the construct retaining only 5 residues of the mature TPT, CAT was found in the cytosolic fraction. Extension of the TPT transit peptide to 23 residues of the mature TPT allowed specific import and processing of CAT into chloroplasts. These results indicate that, despite its unusual structure, the TPT transit peptide is able to target a passenger protein specifically into chloroplasts, provided that NH2-terminal residues of the mature TPT are still present. The discrepancy between the in vitro and in vivo data suggests that the translocation machinery is more stringent in the latter case and that sorting of proteins might not be addressed adequately by in vitro experiments.

Protein import into mitochondria

Mitochondria import many hundreds of different proteins that are encoded by nuclear genes. These proteins are targeted to the mitochondria, translocated through the mitochondrial membranes, and sorted to the different mitochondrial subcompartments. Separate translocases in the mitochondrial outer membrane (TOM complex) and in the inner membrane (TIM complex) facilitate recognition of preproteins and transport across the two membranes. Factors in the cytosol assist in targeting of preproteins. Protein components in the matrix partake in energetically driving translocation in a reaction that depends on the membrane potential and matrix-ATP. Molecular chaperones in the matrix exert multiple functions in translocation, sorting, folding, and assembly of newly imported proteins.

Transport of proteins in eukaryotic cells: more questions ahead

Some newly synthesized proteins contain signals that direct their transport to their final location within or outside of the cell. Targeting signals are recognized by specific protein receptors located either in the cytoplasm or in the membrane of the target organelle. Specific membrane protein complexes are involved in insertion and translocation of polypeptides across the membranes. Often, additional targeting signals are required for a polypeptide to be further transported to its site of function. In this review, we will describe the trafficking of proteins to various cellular organelles (nucleus, chloroplasts, mitochondria, peroxisomes) with emphasis on transport to and through the secretory pathway.

Mitochondrial and chloroplast targeting sequences in tandem modify protein import specificity in plant organelles

Protein targeting to plant mitochondria and chloroplasts is usually very specific and involves targeting sequences located at the amino terminus of the precursor. We challenged the system by using combinations of mitochondrial and chloroplast targeting sequences attached to reporter genes. The sequences coding for the presequence of the mitochondrial F1-ATPase beta-subunit and the transit peptide of the chloroplast chlorophyll a/b-binding protein, both from Nicotiana plumbaginifolia, were fused together in both combinations, then linked to the reporter genes, chloramphenicol acetyl transferase (CAT) and beta-glucuronidase (GUS), and introduced into tobacco. Analysis of CAT and GUS activities and proteins in the subcellular fractions revealed that the chloroplast transit peptide alone was not sufficient to target the reporter proteins to chloroplasts. However, when the mitochondrial beta-presequence was inserted downstream of the chloroplast sequence, import of CAT and GUS into chloroplasts was observed. Using the reciprocal system, the mitochondrial presequence alone was able to direct transport of CAT and, to a lesser extent, GUS to mitochondria; the GUS targeting to mitochondria was increased when the chloroplast targeting sequence was linked downstream of the mitochondrial presequence. Immunodetection experiments using subcellular fractions confirmed the results observed by enzymatic assays. These results indicate the importance of the amino-terminal position of the targeting sequence in determining protein import specificity and are considered within the hypothesis of a co-translational protein import.

Purification and characterization of a tRNA nucleotidyltransferase from Lupinus albus and functional complementation of a yeast mutation by corresponding cDNA

ATP (CTP):tRNA nucleotidyltransferase (EC 2.7.7.25) was purified to apparent homogeneity from a crude extract of Lupinus albus seeds. Purification was accomplished using a multistep protocol including ammonium sulfate fractionation and chromatography on anion-exchange, hydroxylapatite and affinity columns. The lupin enzyme exhibited a pH optimum and salt and ion requirements that were similar to those of tRNA nucleotidyltransferases from other sources. Oligonucleotides, based on partial amino acid sequence of the purified protein, were used to isolate the corresponding cDNA. The cDNA potentially encodes a protein of 560 amino acids with a predicted molecular mass of 64 164 Da in good agreement with the apparent molecular mass of the pure protein determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The size and predicted amino acid sequence of the lupin enzyme are more similar to the enzyme from yeast than from Escherichia coli with some blocks of amino acid sequence conserved among all three enzymes. Functionality of the lupin cDNA was shown by complementation of a temperature-sensitive mutation in the yeast tRNA nucleotidyltransferase gene. While the lupin cDNA compensated for the nucleocytoplasmic defect in the yeast mutant it did not enable the mutant strain to grow at the non-permissive temperature on a non-fermentable carbon source.

Sorting of nuclear-encoded chloroplast membrane proteins to the envelope and the thylakoid membrane

The spinach triose phosphate/phosphate translocator and the 37-kDa protein are both integral components of the chloroplast inner envelope membrane. They are synthesized in the cytosol with N-terminal extensions, the transit peptides, that are different in structural terms from those of imported stromal or thylakoid proteins. In order to determine if these N-terminal extensions are essential for the correct localization to the envelope membrane, they were linked to the mature parts of thylakoid membrane proteins, the light-harvesting chlorophyll a/b binding protein and the CF0II-subunit of the thylakoid ATP synthase, respectively. In addition, the transit peptide of the CF0II-subunit that contains signals for the transport across both the envelope and the thylakoid membrane was fused to the mature parts of both envelope membrane proteins. The chimeric proteins were imported into isolated spinach chloroplasts, and the intraorganellar routing of the proteins was analyzed. The results obtained show that the N-terminal extensions of both envelope membrane proteins possess a stroma-targeting function only and that the information for the integration into the envelope membrane is contained in the mature parts of the proteins. At least part of the integration signal is provided by hydrophobic domains in the mature sequences since the removal of such a hydrophobic segment from the 37-kDa protein leads to missorting of the protein to the stroma and the thylakoid membrane.

Peculiar properties of the PsaF photosystem I protein from the green alga Chlamydomonas reinhardtii: presequence independent import of the PsaF protein into both chloroplasts and mitochondria

It has previously been shown that presequences of nuclear-encoded chloroplast proteins from the green alga Chlamydomonas reinhardtii contain a region that may form an amphiphilic alpha-helix, a structure characteristic of mitochondrial presequences. We have tested two precursors of chloroplast proteins (the PsaF and PsaK photosystem I subunits) from C. reinhardtii for the ability to be imported into spinach leaf mitochondria in vitro. Both precursors bound to spinach mitochondria. The PsaF protein was converted into a protease-protected form with high efficiency in a membrane potential-dependent manner, indicating that the protein had been imported, whereas the PsaK protein was not protease protected. The protease protection of PsaF was not inhibited by a synthetic peptide derived from the presequence of the N. plumbaginifolia mitochondrial F1 beta subunit. Furthermore, if the presequence of PsaF was truncated or deleted by in vitro mutagenesis, the protein was still protease-protected with approximately the same efficiency as the full-length precursor. These results indicate that PsaF can be imported by spinach mitochondria in a presequence-independent manner. However, even in the absence of the presequence, this process was membrane potential-dependent. Interestingly, the presequence-truncated PsaF proteins were also protease-protected upon incubation with C. reinhardtii chloroplasts. Our results indicate that the C. reinhardtii chloroplast PsaF protein has peculiar properties and may be imported not only into chloroplasts but also into higher-plant mitochondria. This finding indicates that additional control mechanisms in the cytosol that are independent of the presequence are required to achieve sorting between chloroplasts and mitochondria in vivo.

Mitochondrial import of subunit Va of cytochrome c oxidase characterized with yeast mutants

We have investigated the unusual import pathway of cytochrome c oxidase subunit Va (COXVa) into the yeast mitochondrial inner membrane by use of mutants that lack import receptors or are defective in matrix hsp70. (i) Mitochondria lacking the receptor MOM72 are not impaired in import of COXVa. Mitochondria lacking the main receptor MOM19 are moderately reduced in import of COXVa; this, however, is caused by a reduction of the inner membrane potential and not by a lack of specific receptor functions. (ii) Mitochondria defective in the unfoldase function of matrix hsp70 efficiently import COXVa, whereas mitochondria defective in the translocase function of the hsp70 are blocked in import of COXVA. A COXVa construct where the internal hydrophobic sorting signal is placed close to the presequence does not require either hsp70 function. These results demonstrate that import of COXVa does not require MOM19 or MOM72, but they unexpectedly reveal a strong dependence on the translocase function of matrix hsp70. Two important implications about the characterization of mitochondrial protein import in general are obtained. First, the interpretation of import results with mutants lacking MOM19 have to consider effects on the membrane potential. Second, the distance between a matrix targeting sequence and a hydrophobic sorting sequence within a precursor appears to determine if the inner membrane sorting machinery can substitute for the translocase function of hsp70 or not.