Characterization of a novel zinc metalloprotease involved in degrading targeting peptides in mitochondria and chloroplasts

We have recently isolated and identified a novel mitochondrial metalloprotease, pre-sequence protease (PreP) from potato and shown that it degrades mitochondrial pre-sequences. PreP belongs to the pitrilysin protease family and contains an inverted zinc-binding motif. To further investigate the degradation of targeting peptides, we have overexpressed the Arabidopsis thaliana homologue of PreP, zinc metalloprotease (Zn-MP), in Escherichia coli . We have characterized the recombinant Zn-MP with respect to its catalytic site, substrate specificity and intracellular localization. Mutagenesis studies of the residues involved in metal binding identified the histidines and the proximal glutamate as essential residues for the proteolytic activity. Substrate specificity studies showed that the Zn-MP has the ability to degrade both mitochondrial pre-sequences and chloroplastic transit peptides, as well as other unstructured peptides. The Zn-MP does not recognize an amino acid sequence per se . Immunological studies and proteolytic activity measurements in isolated mitochondria and chloroplasts revealed the presence of the Zn-MP in both organelles. Furthermore, the Zn-MP was found to be dually imported to both mitochondria and chloroplasts in vitro . In summary, our data show that the Zn-MP is present and serves the same function in chloroplasts as in mitochondria – degradation of targeting peptides.     

Two novel mitochondrial and chloroplastic targeting-peptide-degrading peptidasomes in A. thaliana, AtPreP1 and AtPreP2

Two novel metalloendopeptidases in Arabidopsis thaliana, AtPreP1 and AtPreP2, are responsible for the degradation of targeting peptides in mitochondria and chloroplasts. Both AtPreP1 and AtPreP2 contain ambiguous targeting peptides and are dually targeted to both organelles. The proteases also have the capacity to degrade unstructured peptides of up to 65 amino acid residues, but not small proteins. The catalysis occurs in a huge catalytic chamber revealed by the crystal structure of AtPreP1 at 2.1 A. The enzymes show a preference for basic and small uncharged amino acids or serines at the cleavage sites. Despite similarities in cleavage specificities, cleavage-site recognition differs for both proteases and is context- and structure-dependent. The AtPreP1 and AtPreP2 genes are differentially expressed in Arabidopsis.     

A novel mitochondrial and chloroplast peptidasome, PreP

A novel mitochondrial and chloroplast peptidasome, the Presequence Protease (PreP) degrades organellar targeting peptides as well as other unstructured peptides up to 65 amino acid residues in length. PreP belongs to the pitrilysin oligopeptidase family (M16C) containing an inverted zinc-binding motif. The crystal structure of Arabidopsis thaliana PreP, AtPreP, refined at 2.1 ?, revealed a novel mechanism of proteolysis in which two halves of the enzyme connected by a hinge region enclose a large catalytic chamber opening and closing in response to peptide binding. Double knock-out mutant of AtPreP1 and AtPreP2 results in a severe phenotype, including decreased size and growth rate, chlorosis and organellar abnormalities, such as altered chloroplast starch content, partial loss of the integrity of the inner mitochondrial membrane and reduced mitochondrial respiration. PreP homologues are also present in yeast and humans. Interestingly, human PreP has been associated with Alzheimer's disease as it is responsible for degradation of amyloid-β peptide in brain mitochondria.     

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.     

Dual targeting of organellar seryl-tRNA synthetase to maize mitochondria and chloroplasts

Aminoacyl-tRNA synthetases (AARSs) play a critical role in translation and are thus required in three plant protein-synthesizing compartments: cytosol, mitochondria and plastids. A systematic study had previously shown extensive sharing of organellar AARSs from Arabidopsis thaliana, mostly between mitochondria and chloroplasts. However, distribution of AARSs from monocot species, such as maize, has never been experimentally investigated. Here we demonstrate dual targeting of maize seryl-tRNA synthetase, SerZMo, into both mitochondria and chloroplasts using combination of complementary methods, including in vitro import assay, transient expression analysis of green fluorescent protein (GFP) fusions and immunodetection. We also show that SerZMo dual localization is established by the virtue of an ambiguous targeting peptide. Full-length SerZMo protein fused to GFP is targeted to chloroplast stromules, indicating that SerZMo protein performs its function in plastid stroma. The deletion mutant lacking N-terminal region of the ambiguous SerZMo targeting peptide was neither targeted into mitochondria nor chloroplasts, indicating the importance of this region in both mitochondrial and chloroplastic import.     

Substitution of the gene for chloroplast RPS16 was assisted by generation of a dual targeting signal

Organelle (mitochondria and chloroplasts in plants) genomes lost a large number of genes after endosymbiosis occurred. Even after this major gene loss, organelle genomes still lose their own genes, even those that are essential, via gene transfer to the nucleus and gene substitution of either different organelle origin or de novo genes. Gene transfer and substitution events are important processes in the evolution of the eukaryotic cell. Gene loss is an ongoing process in the mitochondria and chloroplasts of higher plants. The gene for ribosomal protein S16 (rps16) is encoded in the chloroplast genome of most higher plants but not in Medicago truncatula and Populus alba. Here, we show that these 2 species have compensated for loss of the rps16 from the chloroplast genome by having a mitochondrial rps16 that can target the chloroplasts as well as mitochondria. Furthermore, in Arabidopsis thaliana, Lycopersicon esculentum, and Oryza sativa, whose chloroplast genomes encode the rps16, we show that the product of the mitochondrial rps16 has dual targeting ability. These results suggest that the dual targeting of RPS16 to the mitochondria and chloroplasts emerged before the divergence of monocots and dicots (140-150 MYA). The gene substitution of the chloroplast rps16 by the nuclear-encoded rps16 in higher plants is the first report about ongoing gene substitution by dual targeting and provides evidence for an intermediate stage in the formation of this heterogeneous organelle.     

Both metaxin and Tom20 together with two mitochondria-specific motifs support mitochondrial targeting of dual-targeting AtSufE1

Plant cells have two endosymbiotic organelles, chloroplasts, and mitochondria. These organelles perform specific functions that depend on organelle-specific proteins. The majority of chloroplast and mitochondrial proteins are specifically imported by the transit peptide and presequence, respectively. However, a significant number of proteins are also dually targeted to these two organelles. Currently, it is not fully understood how proteins are dually targeted to both chloroplasts and mitochondria. In this study, the mechanism underlying mitochondrial targeting of dual targeting AtSufE1 in Arabidopsis was elucidated. The N-terminal fragment containing 80 residues of AtSufE1 (AtSufE1N80) was sufficient to confer dual targeting of reporter protein, AtSufE1N80:GFP, in protoplasts. Two sequence motifs, two arginine residues at 15^th and 21^st positions, and amino acid (aa) sequence motif AKTLLLRPLK from the 31^st to 40^th aa position, were responsible for targeting to mitochondria a portion of reporter proteins amid the chloroplast targeting. The sequence motif PSEVPFRRT from the 41^st to 50^th aa position constitutes a common motif for targeting to both chloroplasts and mitochondria. For mitochondrial import of AtSufE1:N80, Metaxin played a critical role. In addition, BiFC and protein pull-down experiments showed that AtSufE1N80 specifically interacts with import receptors, Metaxin and Tom20. The interaction of AtSufE1N80 with Metaxin was required for the interaction with Tom20. Based on these results, we propose that mitochondrial targeting of dual-targeting AtSufE1 is mediated by both mitochondria-specific and common sequence motifs in the signal sequence through the interaction with import receptors, Metaxin and Tom20, in a successive manner.     

Two novel targeting peptide degrading proteases, PrePs, in mitochondria and chloroplasts, so similar and still different

Two novel metalloproteases from Arabidopsis thaliana, termed AtPrePI and AtPrePII, were recently identified and shown to degrade targeting peptides in mitochondria and chloroplasts using an ambiguous targeting peptide. AtPrePI and AtPrePII are classified as dually targeted proteins as they are targeted to both mitochondria and chloroplasts. Both proteases harbour an inverted metal binding motif and belong to the pitrilysin subfamily A. Here we have investigated the subsite specificity of AtPrePI and AtPrePII by studying their proteolytic activity against the mitochondrial F(1)beta pre-sequence, peptides derived from the F(1)beta pre-sequence as well as non-mitochondrial peptides and proteins. The degradation products were analysed, identified by MALDI-TOF spectrometry and superimposed on the 3D structure of the F(1)beta pre-sequence. AtPrePI and AtPrePII cleaved peptides that are in the range of 10 to 65 amino acid residues, whereas folded or longer unfolded peptides and small proteins were not degraded. Both proteases showed preference for basic amino acids in the P(1) position and small, uncharged amino acids or serine residues in the P'(1) position. Interestingly, both AtPrePI and AtPrePII cleaved almost exclusively towards the ends of the alpha-helical elements of the F(1)beta pre-sequence. However, AtPrePI showed a preference for the N-terminal amphiphilic alpha-helix and positively charged amino acid residues and degraded the F(1)beta pre-sequence into 10-16 amino acid fragments, whereas AtPrePII did not show any positional preference and degraded the F(1)beta pre-sequence into 10-23 amino acid fragments. In conclusion, despite the high sequence identity between AtPrePI and AtPrePII and similarities in cleavage specificities, cleavage site recognition differs for both proteases and is context and structure dependent.     

How can organellar protein N-terminal sequences be dual targeting signals? In silico analysis and mutagenesis approach

Organellar nuclear-encoded proteins can be mitochondrial, chloroplastic or localized in both mitochondria and chloroplasts. Most of the determinants for organellar targeting are localized in the N-terminal part of the proteins, which were therefore analyzed in Arabidopsis thaliana. The mitochondrial, chloroplastic and dual N-terminal sequences have an overall similar composition. However, Arg is rare in the first 20 residues of chloroplastic and dual sequences, and Ala is more frequent at position 2 of these two types of sequence as compared to mitochondrial sequences. According to these observations, mutations were performed in three dual targeted proteins and analyzed by in vitro import into isolated mitochondria and chloroplasts. First, experiments performed with wild-type proteins suggest that the binding of precursor proteins to mitochondria is highly efficient, whereas the import and processing steps are more efficient in chloroplasts. Moreover, different processing sites are recognized by the mitochondrial and chloroplastic processing peptidases. Second, the mutagenesis approach shows the positive role of Arg residues for enhancing mitochondrial import or processing, as expected by the in silico analysis. By contrast, mutations at position 2 have dramatic and unpredicted effects, either enhancing or completely abolishing import. This suggests that the nature of the second amino acid residue of the N-terminal sequence is essential for the import of dual targeted sequences.     

Arabidopsis thaliana ferrochelatase-I and -II are not imported into Arabidopsis mitochondria

Using in vitro import assays into purified mitochondria and chloroplasts we found that Arabidopsis ferrochelatase-I and ferrochelatase-II were not imported into mitochondria purified from Arabidopsis (or several other plants) but were imported into pea leaf chloroplasts. Other dual targeted proteins could be imported into purified mitochondria from Arabidopsis. As only two ferrochelatase genes are present in the completed Arabidopsis genome, the presence of ferrochelatase activity in plant mitochondria needs to be re-evaluated. Previous reports of Arabidopsis ferrochelatase-I import into pea mitochondria are due to the fact that pea leaf (and root) mitochondria appear to import a variety, but not all chloroplast proteins. Thus pea mitochondria are not a suitable system to either study dual targeting, or to distinguish between isozymes present in mitochondria and chloroplasts.     

Dual targeting and function of a protease in mitochondria and chloroplasts

Here we show, using the green fluorescent protein (GFP) fusion system, that an Arabidopsis thaliana zinc-metalloprotease (AtZn-MP) is targeted to both mitochondria and chloroplasts. A deletion mutant lacking the amino-terminal 28 residues, with translation initiation at the second methionine residue, was imported into chloroplasts only. However, a mutated form of the full-length targeting peptide, in which the second methionine residue is changed to leucine, was imported to both organelles. No GFP fluorescence was detected when a frame-shift mutation was introduced between the first and second ATG codons of the Zn-MP–GFP construct, suggesting no alternative translational initiation. Our results show that the dual targeting of the Zn-MP is due to an ambiguous targeting peptide. Furthermore, we show that the recombinant AtZn-MP degrades mitochondrial and chloroplastic targeting peptides, indicating its function as a signal peptide degrading protease in both mitochondria and chloroplasts.     

NMR investigations of the dual targeting peptide of Thr-tRNA synthetase and its interaction with the mitochondrial Tom20 receptor in Arabidopsis thaliana

Most mitochondrial proteins are synthesized in the cytosol as precursor proteins containing an N-terminal targeting peptide and are imported into mitochondria through the import machineries, the translocase of the outer mitochondrial membrane (TOM) and the translocase of the inner mitochondrial membrane (TIM). The N-terminal targeting peptide of precursor proteins destined for the mitochondrial matrix is recognized by the Tom20 receptor and plays an important role in the import process. Protein import is usually organelle specific, but several plant proteins are dually targeted into mitochondria and chloroplasts using an ambiguous dual targeting peptide. We present NMR studies of the dual targeting peptide of Thr-tRNA synthetase and its interaction with Tom20 in Arabidopsis?thaliana. Our findings show that the targeting peptide is mostly unstructured in buffer, with a propensity to form α-helical structure in one region, S6-F27, and a very weak β-strand propensity for Q34-Q38. The α-helical structured region has an amphiphilic character and a φχχφφ motif, both of which have previously been shown to be important for mitochondrial import. Using NMR we have mapped out two regions in the peptide that are important for Tom20 recognition: one of them, F9-V28, overlaps with the amphiphilic region, and the other comprises residues L30-Q39. Our results show that the targeting peptide may interact with Tom20 in several ways. Furthermore, our results indicate a weak, dynamic interaction. The results provide for the first time molecular details on the interaction of the Tom20 receptor with a dual targeting peptide. DATABASE: The backbone chemical shift assignments for ThrRS-dTP(2-60) have been deposited with the Biological Magnetic Resonance Bank (BMRB) under the accession code 18248 STRUCTURED DIGITAL ABSTRACT: ThrRS-dTP?and?Tom20-4?bind?by?nuclear magnetic resonance?(View interaction).     

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.     

A truncated analog of a pre-light-harvesting chlorophyll a/b protein II transit peptide inhibits protein import into chloroplasts

It is unclear how transit peptides target nuclear-encoded precursor proteins to the chloroplast. This study establishes the feasibility of using synthetic peptides as competitive inhibitors of chloroplast protein import and as probes for the function of domains within transit peptides. We show that peptide pL(1-20), MAASTMALSSPAFAGKAVNY, an analog of the NH2 terminus of a pre-light harvesting chlorophyll a/b protein II from Arabidopsis, inhibits the import of several Arabidopsis and pea precursor proteins into pea chloroplasts. Inhibition occurs at a step between the initial binding of precursors to the chloroplast and the first proteolytic cleavage event and is not due to interference with ATP availability or chloroplast integrity. Presumably this reflects specific binding of the peptide to the import machinery in the chloroplast envelope. Our data are consistent with the suggestion (Karlin-Neumann, G. A., and Tobin, E. M. (1986) EMBO J. 5, 9-13) that two conserved blocks of amino acids near the NH2-terminus of transit peptides (spanned by peptide pL(1-20] participate in protein targeting. Computer analysis also shows peptide pL(1-20) lacks the amphiphilic properties characteristic of pre-sequences of many nuclear-encoded mitochondrial proteins. This shows a difference in the mechanisms for targeting proteins to chloroplasts and mitochondria.     

Defining the Determinants for Dual Targeting of Amino Acyl-tRNA Synthetases to Mitochondria and Chloroplasts

Most of the organellar amino acyl-tRNA synthetases (aaRSs) are dually targeted to both mitochondria and chloroplasts using dual targeting peptides (dTPs). We have investigated the targeting properties and domain structure of dTPs of seven aaRSs by studying the in vitro and in vivo import of N-terminal deleted constructs of dTPs fused to green fluorescent protein. The deletion constructs were designed based on prediction programs, TargetP and Predotar, as well as LogoPlots derived from organellar proteomes in Arabidopsis thaliana. In vitro import was performed either into a single isolated organelle or as dual import (i.e., into a mixture of isolated mitochondria and chloroplasts followed by reisolation of the organelles). In vivo import was investigated as transient expression of the green fluorescent protein constructs in Nicotiana benthamiana protoplasts. Characterization of recognition determinants showed that the N-terminal portions of TyrRS-, ValRS- and ThrRS-dTPs (27, 22 and 23 amino acids, respectively) are required for targeting into both mitochondria and chloroplasts. Surprisingly, these N-terminal portions contain no or very few arginines (or lysines) but very high number of hydroxylated residues (26-51%). For two aaRSs, a domain structure of the dTP became evident. Removal of 20 residues from the dTP of ProRS abolished chloroplastic import, indicating that the N-terminal region was required for chloroplast targeting, whereas deletion of 16 N-terminal amino acids from AspRS-dTP inhibited the mitochondrial import, showing that in this case, the N-terminal portion was required for the mitochondrial import. Finally, deletion of N-terminal regions of dTPs for IleRS and LysRS did not affect dual targeting. In summary, it can be concluded that there is no general rule for how the determinants for dual targeting are distributed within dTPs; in most cases, the N-terminal portion is essential for import into both organelles, but in a few cases, a domain structure was observed.     

Binding of divalent cations is essential for the activity of the organellar peptidasome in Arabidopsis thaliana, AtPreP

The dual-targeted mitochondrial and chloroplastic zinc metallooligopeptidase from Arabidopsis, AtPreP, functions as a peptidasome that degrades targeting peptides and other small unstructured peptides. In addition to Zn located in the catalytic site, AtPreP also contains two Mg-binding sites. We have investigated the role of Mg-binding using AtPreP variants, in which one or both sites were rendered unable to bind Mg²⁺. Our results show that metal binding besides that of the active site is crucial for AtPreP proteolysis, particularly the inner site appears essential for normal proteolytic function. This is also supported by its evolutionary conservation among all plant species of PreP.

Structured summary

MINT-7231937, MINT-7232017, MINT-7232035, MINT-7232051, MINT-7232070, MINT-7232090:AtPreP1 (uniprotkb:Q9LJL3) enzymaticly reacts (MI:0414) pF1 beta (uniprotkb:P17614) by protease assay (MI:0435)MINT-7232132:AtPreP1 (uniprotkb:Q9LJL3) enzymaticly reacts (MI:0414) galanin (uniprotkb:P22466) by protease assay (MI:0435)MINT-7232175:AtPreP1 (uniprotkb:Q9LJL3) enzymaticly reacts (MI:0414) Cecropin A (uniprotkb:P14954) by protease assay (MI:0435)MINT-7232163:AtPreP1 (uniprotkb:Q9LJL3) enzymaticly reacts (MI:0414) hPrPss (uniprotkb:P04156) by protease assay (MI:0435)     

The signal distinguishing between targeting of outer membrane β-barrel protein to plastids and mitochondria in plants

The proteome of the outer membrane of mitochondria and chloroplasts consists of membrane proteins anchored by α-helical or β-sheet elements. While proteins with α-helical transmembrane domains are present in all cellular membranes, proteins with β-barrel structure are specific for these two membranes. The organellar β-barrel proteins are encoded in the nuclear genome and thus, have to be targeted to the outer organellar membrane where they are recognized by surface exposed translocation complexes. In the last years, the signals that ensure proper targeting of these proteins have been investigated as essential base for an understanding of the regulation of cellular protein distribution. However, the organellar β-barrel proteins are unique as most of them do not contain a typical targeting information in form of an N-terminal cleavable targeting signal. Recently, it was discovered that targeting and surface recognition of mitochondrial β-barrel proteins in yeast, humans and plants depends on the hydrophobicity of the last β-hairpin of the β-barrel. However, we demonstrate that the hydrophobicity is not sufficient for the discrimination of targeting to chloroplasts or mitochondria. By domain swapping between mitochondrial and chloroplast targeted β-barrel proteins atVDAC1 and psOEP24 we demonstrate that the presence of a hydrophilic amino acid at the C-terminus of the penultimate β-strand is required for mitochondrial targeting. A mutation of the chloroplast β-barrel protein psOEP24 which mimics such profile is efficiently targeted to mitochondria. Thus, we present the properties of the signal for mitochondrial targeting of β-barrel proteins in plants.     

Chloroplast proteases: possible regulators of gene expression?

A wide range of proteolytic processes in the chloroplast are well recognized. These include processing of precursor proteins, removal of oxidatively damaged proteins, degradation of proteins missing their prosthetic groups or their partner subunit in a protein complex, and adjustment of the quantity of certain chloroplast proteins in response to changing environmental conditions. To date, several chloroplast proteases have been identified and cloned. The chloroplast processing enzyme is responsible for removing the transit peptides of newly imported proteins. The thylakoid processing peptidase removes the thylakoid-transfer domain from proteins translocated into the thylakoid lumen. Within the lumen, Tsp removes the carboxy-terminal tail of the precursor of the PSII D1 protein. In contrast to these processing peptidases which perform a single endo-proteolytic cut, processive proteases that can completely degrade substrate proteins also exist in chloroplasts. The serine ATP-dependent Clp protease, composed of the proteolytic subunit ClpP and the regulatory subunit ClpC, is located in the stroma, and is involved in the degradation of abnormal soluble and membrane-bound proteins. The ATP-dependent metalloprotease FtsH is bound to the thylakoid membrane, facing the stroma. It degrades unassembled proteins and is involved in the degradation of the D1 protein of PSII following photoinhibition. DegP is a serine protease bound to the lumenal side of the thylakoid membrane that might be involved in the chloroplast response to heat. All these peptidases and proteases are homologues of known bacterial enzymes. Since ATP-dependent bacterial proteases and their mitochondrial homologues are also involved in the regulation of gene expression, via their determining the levels of key regulatory proteins, chloroplast proteases are expected to play a similar role.