THE ROLE OF CARBONIC ANHYDRASE IN THE FORMATION OF MOUGEOTIA (CHAROPHYCEAE) BLOOMS IN ACIDIC ENVIRONMENTS

Diatoms and related algae have plastids that are surrounded by four membranes. The outer two membranes are continuous with the endoplasmic reticulum and the inner two membranes are analogous to the plastid envelope membranes of higher plants and green algae. Thus the plastids are completely compartmentalized within the ER membranes. The targeting presequences for nuclear-encoded plastid proteins have two recognizable domains. The first domain is a classic signal sequence, which presumably targets the proteins to the endoplasmic reticulum. The second domain has characteristics of a transit peptide, which targets proteins to the plastids of higher plants. To characterize these targeting domains, the presequence from the nuclear-encoded plastid protein AtpC was utilized. A series of deletions of this presequence were fused to Green Fluorescent Protein (GFP) and transformed into cells of the diatom, Phaeodactylum tricornutum. The intracelluar localization of GFP was visualized by fluorescence microscopy. This work demonstrates that the first domain of the presequence is responsible for targeting proteins to the ER lumen and is the essential first step in the plastid protein import process. The second domain is responsible to directing proteins from the ER and through the plastid envelope and only a short portion of the transit peptide-like domain is necessary to complete this second processing step. In vivo data generated from this study in a fully homologous transformation system has confirmed Gibbs' hypothesis regarding a multistep import process for plastid proteins in chromophytic algae.     

Identification and characterization of a new conserved motif within the presequence of proteins targeted into complex diatom plastids

Several groups of algae evolved by secondary endocytobiosis, which is defined as the uptake of a eukaryotic alga into a eukaryotic host cell and the subsequent transformation of the endosymbiont into an organelle. Due to this explicit evolutionary history such algae possess plastids that are surrounded by either three or four membranes. Protein targeting into plastids of these organisms depends on N-terminal bipartite presequences consisting of a signal and a transit peptide domain. This suggests that different protein targeting systems may have been combined during establishment of secondary endocytobiosis to enable the transport of proteins into the plastids. Here we demonstrate the presence of an apparently new type of transport into diatom plastids. We analyzed protein targeting into the plastids of diatoms and identified a conserved amino acid sequence motif within plastid preprotein targeting sequences. We expressed several diatom plastid presequence:GFP fusion proteins with or without modifications within that motif in the diatom Phaeodactylum tricornutum and found that a single conserved phenylalanine is crucial for protein transport into the diatom plastids in vivo, thus indicating the presence of a so far unknown new type of targeting signal. We also provide experimental data about the minimal requirements of a diatom plastid targeting presequence and demonstrate that the signal peptides of plastid preproteins and of endoplasmic reticulum-targeted preproteins in diatoms are functionally equivalent. Furthermore we show that treatment of the cells with Brefeldin A arrests protein transport into the diatom plastids suggesting that a vesicular transport step within the plastid membranes may occur.     

IN VIVO CHARACTERIZATION OF THE DIATOM MULTIPARTATE PLASTID TARGETING SIGNAL

Diatoms and related algae have plastids that are surrounded by four membranes. The outer two membranes are continuous with the endoplasmic reticulum and the inner two membranes are analogous to the plastid envelope membranes of higher plants and green algae. Thus the plastids are completely compartmentalized within the ER membranes. The targeting presequences for nuclear‐encoded plastid proteins have two recognizable domains. The first domain is a classic signal sequence, which presumably targets the proteins to the endoplasmic reticulum. The second domain has characteristics of a transit peptide, which targets proteins to the plastids of higher plants. To characterize these targeting domains, the presequence from the nuclear‐encoded plastid protein AtpC was utilized. A series of deletions of this presequence were fused to Green Fluorescent Protein (GFP) and transformed into cells of the diatom, Phaeodactylum tricornutum. The intracelluar localization of GFP was visualized by fluorescence microscopy. This work demonstrates that the first domain of the presequence is responsible for targeting proteins to the ER lumen and is the essential first step in the plastid protein import process. The second domain is responsible to directing proteins from the ER and through the plastid envelope and only a short portion of the transit peptide‐like domain is necessary to complete this second processing step. In vivo data generated from this study in a fully homologous transformation system has confirmed Gibbs' hypothesis regarding a multistep import process for plastid proteins in chromophytic algae.     

Presequence Acquisition During Secondary Endocytobiosis and thePossible Role of Introns

Targeting of nucleus-encoded proteins into chloroplasts is mediated by N-terminal presequences. During evolution of plastids from formerly free-living cyanobacteria by endocytobiosis, genes for most plastid proteins have been transferred from the plastid genome to the nucleus and subsequently had to be equipped with such plastid targeting sequences. So far it is unclear how the gene domains coding for presequences and the respective mature proteins may have been assembled. While land plant plastids are supposed to originate from a primary endocytobiosis event (a prokaryotic cyanobacterium was taken up by a eukaryotic cell), organisms with secondary plastids like diatoms experienced a second endocytobiosis step involving a eukaryotic alga taken up by a eukaryotic host cell. In this group of algae, apparently most genes encoding chloroplast proteins have been transferred a second time (from the nucleus of the endosymbiont to the nucleus of the secondary host) and thus must have been equipped with additional targeting signals. We have analyzed cDNAs and the respective genomic DNA fragments of seven plastid preproteins from the diatom Phaeodactylum tricornutum. In all of these genes we found single spliceosomal introns, generally located within the region coding for the N-terminal plastid targeting sequences or shortly downstream of it. The positions of the introns can be related to the putative phylogenetic histories of the respective genes, indicating that the bipartite targeting sequences in these secondary algae might have evolved by recombination events via introns.The nucleotide sequences have been deposited at Genbank under accession numbers AY191862, AY191863, AY191864, AY191865, AY191866, AY191867, and AY191868.     

Protein targeting into complex diatom plastids: functional characterisation of a specific targeting motif

Plastids of diatoms and related algae evolved by secondary endocytobiosis, the uptake of a eukaryotic alga into a eukaryotic host cell and its subsequent reduction into an organelle. As a result diatom plastids are surrounded by four membranes. Protein targeting of nucleus encoded plastid proteins across these membranes depends on N-terminal bipartite presequences consisting of a signal and a transit peptide-like domain. Diatoms and cryptophytes share a conserved amino acid motif of unknown function at the cleavage site of the signal peptides (ASAFAP), which is particularly important for successful plastid targeting. Screening genomic databases we found that in rare cases the very conserved phenylalanine within the motif may be replaced by tryptophan, tyrosine or leucine. To test such unusual presequences for functionality and to better understand the role of the motif and putative receptor proteins involved in targeting, we constructed presequence:GFP fusion proteins with or without modifications of the “ASAFAP”-motif and expressed them in the diatom Phaeodactylum tricornutum. In this comprehensive mutational analysis we found that only the aromatic amino acids phenylalanine, tryptophan, tyrosine and the bulky amino acid leucine at the +1 position of the predicted signal peptidase cleavage site allow plastid import, as expected from the sequence comparison of native plastid targeting presequences of P. tricornutum and the cryptophyte Guillardia theta. Deletions within the signal peptide domains also impaired plastid import, showing that the presence of F at the N-terminus of the transit peptide together with a cleavable signal peptide is crucial for plastid import. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. A. Gruber and S. Vugrinec contributed equally to this work.     

Simultaneous targeting of pea glutathione reductase and of a bacterial fusion protein to chloroplasts and mitochondria in transgenic tobacco

N-terminal presequences from cDNAs encoding mitochondrion- or chloroplast-specific proteins are able, with variable efficiencies, to target preproteins to their respective organelles. In the few cases studied in which a nuclear-encoded protein is found in both these organelles, each compartment-specific isoform is encoded by a separate gene. Glutathione reductase (GR) from peas is encoded by a single nuclear gene and yet GR is distributed between chloroplasts, mitochondria and the cytosol. Previous sequence analysis of a full-length GR cDNA revealed the presence of a putative plastid transit peptide. However, expression of this cDNA in transgenic tobacco resulted in substantially elevated GR activities in both chloroplasts and mitochondria in four independent lines examined. There was no effect on expression of the endogenous tobacco GR genes. Replacement of the GR presequence with presequences from pea rbcS (chloroplast) and Nicotiana plumbaginifolia Mn-SOD (mitochondrion) resulted in targeting of GR only into the appropriate organelle. Expression of a fusion protein between the amino terminal region of GR and phosphinothricin acetyl transferase resulted in targeting of the foreign protein to chloroplasts and mitochondria. Thus, the pea GR presequence is capable of co-targeting this enzyme or a foreign protein to chloroplasts and mitochondria in vivo . This is the first example of co-targeting by a higher plant preprotein.     

Peptide library approach with a disulfide tether to refine the Tom20 recognition motif in mitochondrial presequences

Many mitochondrial matrix and inner-membrane proteins are synthesized in the cytosol as precursor proteins with an N-terminal presequence, and are imported into the mitochondria. Although no distinct sequence homology has been found among mitochondrial presequences, Tom20, a general import receptor in the outer mitohcondrial membrane, binds to presequences, and distinguishes mitochondrial proteins from non-mitochonrial proteins. The recently determined structure of the cytosolic domain of Tom20 (DeltaTom20) in a complex with the presequence of rat aldehyde dehydrogenase (ALDH) showed that a short stretch of the presequence forms an amphiphilic helix, and its hydrophobic surface interacts with the hydrophobic-binding groove of Tom20. The following NMR analyses revealed a common five-residue pattern for Tom20 binding in five different presequences. To refine the common amino acid motif for the recognition by Tom20, we introduced a new peptide library approach in this study: we prepared a mixture of ALDH presequence variants, tethered these peptides to DeltaTom20 in a competitive manner by an intermolecular disulfide bond, and determined the relative affinities by MALDI-TOF mass spectrometry. We successfully deduced a refined, common motif for the recognition by Tom20, and found that the segment consisting of residues 14-20 of the ALDH presequence was locally optimized in the sequence space, with respect to Tom20 binding.     

Isolation of mitochondrial and plastid ftsZ genes and analysis of the organelle targeting sequence in the diatom Chaetoceros neogracile (Diatoms,Bacillariophyceae)

Mitochondria and plastids multiply by division in eukaryotic cells. Recently, the eukaryotic homolog of the bacterial cell division protein FtsZ was identified and shown to play an important role in the organelle division process inside the inner membrane. To explore the evolution of FtsZ proteins, and to accumulate data on the protein import system in mitochondria and plastids of the red algal lineage, one mitochondrial and three plastid ftsZ genes were isolated from the diatom Chaetoceros neogracile, whose plastids were acquired by secondary endosymbiotic uptake of a red alga. Protein import into organelles depends on the N‐terminal organelle targeting sequences. N‐terminal bipartite presequences consisting of an endoplasmic reticulum signal peptide and a plastid transit peptide are required for protein import into diatom plastids. To characterize the organelle targeting peptides of C. neogracile, we observed the localization of each green fluorescent protein‐tagged predicted organelle targeting peptide in cultured tobacco cells and diatom cells. Our data suggested that each targeting sequences functioned both in tobacco cultured cells and diatom cells.     

NMR identification of the Tom20 binding segment in mitochondrial presequences

Many mitochondrial proteins are synthesized in the cytosol as precursors with N-terminal presequences, and are imported into mitochondria with the aid of translocator protein complexes containing presequence-binding proteins. Tom20, a receptor protein which functions in an early step of the mitochondrial protein import, recognizes presequences with divergent amino acid sequences. Here, we report the identification of the segments involved in binding to Tom20 in mitochondrial presequences. We monitored the chemical shift perturbation of the NMR signals of five different 15N-labeled presequence peptides by the addition of the cytosolic receptor domain of rat or yeast Tom20. The perturbed segments occupy different positions, either near the N terminus or at the C terminus, in the presequences. Spin label experiments revealed that this is not due to different orientations of the presequence peptides bound to Tom20. The results presented here will offer a starting point to perform detailed analyses of Tom20-binding elements by systematic amino acid replacements.     

Complex protein targeting to dinoflagellate plastids

Protein trafficking pathways to plastids are directed by N-terminal targeting peptides. In plants this consists of a relatively simple transit peptide, while in organisms with secondary plastids (which reside within the endomembrane system) a signal peptide is appended to the transit peptide. Despite amino acid compositional differences between organisms, often due to nucleotide biases, the features of plastid targeting sequences are generally consistent within species. Dinoflagellate algae deviate from this trend. We have conducted an expressed sequence tag (EST) survey of the peridinin-plastid containing dinoflagellate Heterocapsa triquetra to identify and characterize numerous targeting presequences of plastid proteins encoded in the nucleus. Consistent with targeting systems present in other secondary plastid-containing organisms, these all possess a canonical signal peptide at their N termini, however two major classes of transit peptides occur. Both classes possess a common N-terminal portion of the transit peptide, but one class of transit peptides contains a hydrophobic domain that has been reported to act as a stop-transfer membrane anchor, temporarily arresting protein insertion into the endoplasmic reticulum. A second class of transit peptide lacks this feature. These two classes are represented approximately equally, and for any given protein the class is conserved across all dinoflagellate taxa surveyed to date. This dichotomy suggests that two mechanisms, perhaps even trafficking routes, may direct proteins to dinoflagellate plastids. A four-residue phenylalanine-based motif is also a consistent feature of H. triquetra transit peptides, which is an ancient feature predating red algae and galucophytes that was lost in green plastids.     

Transport of peroxisomal proteins synthesized as large precursors in plants

Plant peroxisomes contain at least four proteins, namely, citrate synthase, malate dehydrogenase, long-chain acyl-CoA oxidase, and 3-ketoacyl-CoA thiolase, which are synthesized as large precursors with an N-terminal cleavable presequence. Each presequence has a conserved domain (R[I/L./Q]-X₅-HL) that is homologous to peroxisomal targeting signal 2 from mammals and yeasts. In addition, a cysteine residue is found at the C-terminal ends of the presequences, whose function has not yet been described. The authors analyzed the function of the presequences and the conserved amino acids using transgenic Arabidopsis plants, which accumulate β-glucuronidase carrying the presequence of the peroxisomal proteins from plants. Immunological and immunocytochemical studies on the transgenic plants showed that a conserved sequence in the extrapeptides is essential for targeting to peroxisomes, and a cysteine residue at the cleavage site is involved in the processing of the presequence. These results suggest that the presequences of the peroxisomal proteins function as targeting signals, and are necessary for the recognition of the processing.     

Recognition and Binding of Mitochondrial Presequences during the Import of Proteins into Mitochondria

Nuclear-encoded mitochondrial proteins are imported into mitochondria due to the presence of a targeting sequence, the presequence, on their amino termini. Presequences, which are typically proteolyzed after a protein has been imported into a mitochondrion, lack any strictly conserved primary structure but are positively charged and are predicted to form amphiphilic -helices. Studies with synthetic peptides corresponding to various presequences argue that presequences can partition nonspecifically into the mitochondrial outer membrane and that the specificity of translocation of precursors into mitochondria may depend on interactions of the presequence with the electrical potential of the inner membrane. Although proteins of the outer membrane that are necessary for the translocation of precursor proteins have been proposed to function as receptors for presequences, the binding of presequences to these proteins has not been demonstrated directly. Proteins of the mitochondrial outer membrane may not be responsible for the specificity of translocation of precursors but may instead function, together with cytosolic molecular chaperones, to maintain precursor proteins in conformations that are competent for translocation as the precursors associate with the mitochondrial surface.     

Analysis of the targeting sequences of an iron-containing superoxide dismutase (SOD) of the dinoflagellate <Emphasis Type="Italic">Lingulodinium polyedrum</Emphasis> suggests function in multiple cellular compartments

One of the proteins targeted to the peridinin plastid of the dinoflagellate Lingulodinium polyedrum is the iron-containing superoxide dismutase (LpSOD). Like dinoflagellate plastid proteins of class II, LpSOD carries a bipartite presequence comprising a signal peptide followed by a transit peptide. Our bioinformatic studies suggest that its signal peptide is atypical, however, and that the entire presequence may function as a mitochondrial targeting signal. It is possible that LpSOD represents a new class of proteins in algae with complex plastids, which are co-targeted to the plastid and mitochondrion. In addition to the ambiguous N-terminal targeting signal, LpSOD contains a potential type-1 peroxisome-targeting signal (PTS1) located at its C-terminus. In accordance with a peroxisome localization of this dismutase, its mRNA has two in-frame AUG codons. Our bioinformatic analyses indicate that the first start codon resides in a much weaker oligonucleotide context than the second one. This suggests that synthesis of the plastid/mitochondrion-targeted and peroxisome-targeted isoforms could proceed through so-called leaky scanning. Moreover, our results show that expression of the two isoforms could be regulated by a 'hairpin' structure located between the first and second start codons.     

Isolation and identification of a novel mitochondrial metalloprotease (PreP) that degrades targeting presequences in plants

Most of the nuclear encoded mitochondrial precursor proteins contain an N-terminal extension called the presequence that carries targeting information and that is cleaved off after import into mitochondria. The presequences are amphiphilic, positively charged, membrane-interacting peptides with a propensity to form alpha-helices. Here we have investigated the proteolysis of the presequences that have been cleaved off inside mitochondria. A presequence derived from the overexpressed F(1)beta subunit of the ATP synthase and specific synthetic fluorescent peptides (Pep Tag Protease assay) have been shown to undergo rapid degradation catalyzed by a matrix located protease. We have developed a three-step chromatographic procedure including affinity and anion exchange chromatography for isolation of the protease from potato tuber mitochondria. Two-dimensional gel electrophoresis of the isolated proteolytically active fraction followed by electrospray ionization-mass spectrometry/mass spectrometry and data base searches allowed identification of the presequence peptide-degrading protease in Arabidopsis thaliana data base as a novel mitochondrial metalloendoprotease with a molecular mass of 105 kDa. The identified metalloprotease contains an inverted zinc-binding motif and belongs to the pitrilysin family.     

Active unfolding of precursor proteins during mitochondrial protein import.

Precursor proteins made in the cytoplasm must be in an unfolded conformation during import into mitochondria. Some precursor proteins have tightly folded domains but are imported faster than they unfold spontaneously, implying that mitochondria can unfold proteins. We measured the import rates of artificial precursors containing presequences of varying length fused to either mouse dihydrofolate reductase or bacterial barnase, and found that unfolding of a precursor at the mitochondrial surface is dramatically accelerated when its presequence is long enough to span both membranes and to interact with mhsp70 in the mitochondrial matrix. If the presequence is too short, import is slow but can be strongly accelerated by urea-induced unfolding, suggesting that import of these 'short' precursors is limited by spontaneous unfolding at the mitochondrial surface. With precursors that have sufficiently long presequences, unfolding by the inner membrane import machinery can be orders of magnitude faster than spontaneous unfolding, suggesting that mhsp70 can act as an ATP-driven force-generating motor during protein import.     

Amphiphilicity is essential for mitochondrial presequence function.

We have shown earlier that a mitochondrial presequence peptide can form an amphiphilic helix. However, the importance of amphiphilicity for mitochondrial presequence function became doubtful when an artificial presequence, designed to be non-amphiphilic, proved to be active as a mitochondrial import signal. We now show experimentally that this 'non-amphiphilic' presequence peptide is, in fact, highly amphiphilic as measured by its ability to insert into phospholipid monolayers and to disrupt phospholipid vesicles. This result, and similar tests on three additional artificial presequences (two functionally active and one inactive), revealed that all active presequences were amphiphilic whereas the inactive presequence was non-amphiphilic. One of the active presequence peptides was non-helical in solution and in the presence of detergent micelles. We conclude that amphiphilicity is necessary for mitochondrial presequence function whereas a helical structure may not be essential.     

Identification of Signals Required for Import of the Soybean FAd Subunit of ATP Synthase into Mitochondria

The requirements for protein import into mitochondria was investigated by using the targeting signal of the F(A)d subunit of soybean mitochondrial ATP synthase attached to two different passenger proteins, its native passenger and soybean alternative oxidase. Both passenger proteins are soybean mitochondrial proteins. Changing hydrophobic residues at positions -24:25 (Phe:Leu), -18:19 (Ile:Leu) and -12:13 (Leu:Ile) of the 31 amino acid cleavable presequence gave more than 50% inhibition of import with both passenger proteins. Some other residues in the targeting signal played a more significant role in targeting of one passenger protein compared to another. Notably changing positive residues (Arg, Lys) had a greater inhibitory affect on import with the native passenger protein, i.e. greater inhibition of import with F(A)d mature protein was observed compared to when alternative oxidase was the mature protein. When using chimeric passenger proteins it was shown that the nature of the mature protein can greatly affect the targeting properties of the presequence. In vivo investigations of the targeting presequence indicated that the presequence of 31 amino acids could not support import of GFP as a passenger protein. However, fusion of the full-length F(A)d coding sequence to GFP did result in mitochondrial localisation of GFP. Using the latter fusion we confirmed the critical role of hydrophobic residues at positions -24:25 and -18:19. These results support the proposal that core mitochondrial targeting features exist in all presequences, but that additional features exist. These features may not be evident with all passenger proteins.     

Direct interaction of mitochondrial targeting presequences with purified components of the TIM23 protein complex

Precursor proteins that are imported from the cytosol into the matrix of mitochondria carry positively charged amphipathic presequences and cross the inner membrane with the help of vital components of the TIM23 complex. It is currently unclear which subunits of the TIM23 complex recognize and directly bind to presequences. Here we analyzed the binding of presequence peptides to purified components of the TIM23 complex. The interaction of three different presequences with purified soluble domains of yeast Tim50 (Tim50IMS), Tim23 (Tim23IMS), and full-length Tim44 was examined. Using chemical cross-linking and surface plasmon resonance we demonstrate, for the first time, the ability of purified Tim50IMS and Tim44 to interact directly with the yeast Hsp60 presequence. We also analyzed their interaction with presequences derived from precursors of yeast mitochondrial 70-kDa heat shock protein (mHsp70) and of bovine cytochrome P450SCC. Moreover, we characterized the nature of the interactions and determined their KDs. On the basis of our results, we suggest a mechanism of translocation where stronger interactions of the presequences on the trans side of the channel support the import of precursor proteins through TIM23 into the matrix.     

Rampant gene loss in the underground orchid Rhizanthella gardneri highlights evolutionary constraints on plastid genomes

Since the endosymbiotic origin of chloroplasts from cyanobacteria 2 billion years ago, the evolution of plastids has been characterized by massive loss of genes. Most plants and algae depend on photosynthesis for energy and have retained ～110 genes in their chloroplast genome that encode components of the gene expression machinery and subunits of the photosystems. However, nonphotosynthetic parasitic plants have retained a reduced plastid genome, showing that plastids have other essential functions besides photosynthesis. We sequenced the complete plastid genome of the underground orchid, Rhizanthella gardneri. This remarkable parasitic subterranean orchid possesses the smallest organelle genome yet described in land plants. With only 20 proteins, 4 rRNAs, and 9 tRNAs encoded in 59,190 bp, it is the least gene-rich plastid genome known to date apart from the fragmented plastid genome of some dinoflagellates. Despite numerous differences, striking similarities with plastid genomes from unrelated parasitic plants identify a minimal set of protein-encoding and tRNA genes required to reside in plant plastids. This prime example of convergent evolution implies shared selective constraints on gene loss or transfer.