The organellar peptidasome,PreP: A journey from Arabidopsis to Alzheimer's disease

The novel peptidasome, called presequence protease, PreP, was originally identified and characterized in Arabidopsis thaliana as a mitochondrial matrix and chloroplast stroma localized metalloprotease. PreP has a function as the organellar peptide clearing protease and is responsible for degrading free targeting peptides and also other unstructured peptides up to 65 amino acid residues that might be toxic to organellar functions. PreP contains an inverted Zn-binding motif and belongs to the pitrilysin protease family. The crystal structure of AtPreP refined at 2.1 Å demonstrated a unique totally enclosed large cavity of 10 000 Å³ that opens and closes in response to peptide binding, revealing a novel catalytic mechanism for proteolysis. Homologues of PreP have been found in yeast and human mitochondria. Interestingly, the human PreP, hPreP, is the protease that is responsible for clearing the human brain mitochondria from the toxic amyloid-β peptide (Aβ) associated with Alzheimer's disease (AD). Accumulation of Aβ has been shown in the brain mitochondria from AD patients and mutant transgenic mice overexpressing Aβ. Here, we present a review of our present knowledge on structural and functional characteristics of PreP and discuss its mitochondrial Aβ-degrading activity in the human brain mitochondria in relation to AD.     

Degradation of the amyloid beta-protein by the novel mitochondrial peptidasome, PreP

Recently we have identified the novel mitochondrial peptidase responsible for degrading presequences and other short unstructured peptides in mitochondria, the presequence peptidase, which we named PreP peptidasome. In the present study we have identified and characterized the human PreP homologue, hPreP, in brain mitochondria, and we show its capacity to degrade the amyloid beta-protein (Abeta). PreP belongs to the pitrilysin oligopeptidase family M16C containing an inverted zinc-binding motif. We show that hPreP is localized to the mitochondrial matrix. In situ immuno-inactivation studies in human brain mitochondria using anti-hPreP antibodies showed complete inhibition of proteolytic activity against Abeta. We have cloned, overexpressed, and purified recombinant hPreP and its mutant with catalytic base Glu(78) in the inverted zinc-binding motif replaced by Gln. In vitro studies using recombinant hPreP and liquid chromatography nanospray tandem mass spectrometry revealed novel cleavage specificities against Abeta-(1-42), Abeta-(1-40), and Abeta Arctic, a protein that causes increased protofibril formation an early onset familial variant of Alzheimer disease. In contrast to insulin degrading enzyme, which is a functional analogue of hPreP, hPreP does not degrade insulin but does degrade insulin B-chain. Molecular modeling of hPreP based on the crystal structure at 2.1 A resolution of AtPreP allowed us to identify Cys(90) and Cys(527) that form disulfide bridges under oxidized conditions and might be involved in redox regulation of the enzyme. Degradation of the mitochondrial Abeta by hPreP may potentially be of importance in the pathology of Alzheimer disease.     

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)     

Import into chloroplasts of a yeast mitochondrial protein directed by ferredoxin and plastocyanin transit peptides

Many chloroplast proteins are synthesized in the cytoplasm as precursors which contain an amino terminal transit peptide. These precursors are subsequently imported into chloroplast and targeted to one of several organellar locations. This import is mediated by the transit peptide, which is cleaved off during import. We have used the transit peptides of ferredoxin (chloroplast stroma) and plastocyanin (thylakoid lumen) to study chloroplast protein import and intra-organellar routing toward different compartments. Chimeric genes were constructed that encode precursor proteins in which the transit peptides are linked to yeast mitochondrial manganese superoxide dismutase. Chloroplast protein import and localization experiments show that both chimeric proteins are imported into the chloroplast stroma and processed. The plastocyanin transit sequence did not direct superoxide dismutase to the thylakoids; this protein was found in the stroma as an intermediate that still contains part of the plastocyanin transit peptide. The organelle specificity of these chimeric precursors reflected the transit peptide parts of the molecules, because neither the ferredoxin and plastocyanin precursors nor the chimeric proteins were imported into isolated yeast mitochondria.     

Mechanism of oxidative inactivation of human presequence protease by hydrogen peroxide

The mitochondrial presequence protease (PreP) is a member of the pitrilysin class of metalloproteases. It degrades the mitochondrial targeting presequences of mitochondria-localized proteins as well as unstructured peptides such as amyloid-β peptide. The specific activity of PreP is reduced in Alzheimer patients and animal models of Alzheimer disease. The loss of activity can be mimicked in vitro by exposure to oxidizing conditions, and indirect evidence suggested that inactivation was due to methionine oxidation. We performed peptide mapping analyses to elucidate the mechanism of inactivation. None of the 24 methionine residues in recombinant human PreP was oxidized. We present evidence that inactivation is due to oxidation of cysteine residues and consequent oligomerization through intermolecular disulfide bonds. The most susceptible cysteine residues to oxidation are Cys34, Cys112, and Cys119. Most, but not all, of the activity loss is restored by the reducing agent dithiothreitol. These findings elucidate a redox mechanism for regulation of PreP and also provide a rational basis for therapeutic intervention in conditions characterized by excessive oxidation of PreP.     

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.     

Mechanism of Peptide Binding and Cleavage by the Human Mitochondrial Peptidase Neurolysin

Proteolysis plays an important role in mitochondrial biogenesis, from the processing of newly imported precursor proteins to the degradation of mitochondrial targeting peptides. Disruption of peptide degradation activity in yeast, plant and mammalian mitochondria is known to have deleterious consequences for organism physiology, highlighting the important role of mitochondrial peptidases. In the present work, we show that the human mitochondrial peptidase neurolysin (hNLN) can degrade mitochondrial presequence peptides as well as other fragments up to 19 amino acids long. The crystal structure of hNLN^E475Q in complex with the products of neurotensin cleavage at 2.7 Å revealed a closed conformation with an internal cavity that restricts substrate length and highlighted the mechanism of enzyme opening/closing that is necessary for substrate binding and catalytic activity. Analysis of peptide degradation in vitro showed that hNLN cooperates with presequence protease (PreP or PITRM1) in the degradation of long targeting peptides and amyloid-β peptide, Aβ1–40, associated with Alzheimer disease, particularly cleaving the hydrophobic fragment Aβ35–40. These findings suggest that a network of proteases may be required for complete degradation of peptides localized in mitochondria.     

Chloroplast SSR polymorphisms in the Compositae and the mode of organellar inheritance in Helianthus annuus

Because organellar genomes are often uniparentally inherited, chloroplast (cp) and mitochondrial (mt) DNA polymorphisms have become the markers of choice for investigating evolutionary issues such as sex-biased dispersal and the directionality of introgression. To the extent that organellar inheritance is strictly maternal, it has also been suggested that the insertion of transgenes into either the chloroplast or mitochondrial genomes would reduce the likelihood of gene escape via pollen flow from crop fields into wild plant populations. In this paper we describe the adaptation of chloroplast simple sequence repeats (cpSSRs) for use in the Compositae. This work resulted in the identification of 12 loci that are variable across the family, seven of which were further shown to be highly polymorphic within sunflower (Helianthus annuus). We then used these markers, along with a novel mtDNA restriction fragment length polymorphism (RFLP), to investigate the mode of organellar inheritance in a series of experimental crosses designed to mimic the initial stages of crop-wild hybridization in sunflower. Although we cannot rule out the possibility of extremely rare paternal transmission, our results provide the best evidence to date of strict maternal organellar inheritance in sunflower, suggesting that organellar gene containment may be a viable strategy in sunflower. Moreover, the portability of these markers suggests that they will provide a ready source of cpDNA polymorphisms for use in evolutionary studies across the Compositae.     

Deletion of an organellar peptidasome PreP affects early development in Arabidopsis thaliana

A novel peptidasome PreP is responsible for degradation of targeting peptides and other unstructured peptides in mitochondria and chloroplasts. Arabidopsis thaliana contains two PreP isoforms, AtPreP1, and AtPreP2. Here we have characterized single and double prep knockout mutants. Immunoblot analysis of atprep1 and atprep2 mutants showed that both isoforms are expressed in all tissues with the highest expression in flowers and siliques; additionally, AtPreP1 accumulated to a much higher level in comparison to AtPreP2. The atprep2 mutant behaved like wild type, whereas deletion of AtPreP1 resulted in slightly pale-green seedlings. Analysis of the atprep1 atprep2 double mutant revealed a chlorotic phenotype in true leaves with diminished chlorophyll a and b content, but unchanged Chl a/b ratio indicating a proportional decrease of both PSI and PSII complexes. Mitochondrial respiratory rates (state 3) were lower and the mitochondria were partially uncoupled. EM pictures on cross sections of the first true leaves showed aberrant chloroplasts, including less grana stacking and less starch granules. Mitochondria with extremely variable size could also be observed. At later developmental stages the plants appeared almost normal. However, all through the development there was a statistically significant decrease of ~40% in the accumulated biomass in the double mutant plants in comparison to wild type. In mitochondria, deletion of AtPreP was not compensated by activation of any peptidolytic activity, whereas chloroplast membranes contained a minor peptidolytic activity not related to AtPreP. In summary, the AtPreP peptidasome is required for efficient plant growth and organelle function particularly during early development.     

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.     

The closed structure of presequence protease PreP forms a unique 10,000 Angstroms3 chamber for proteolysis

Presequence protease PreP is a novel protease that degrades targeting peptides as well as other unstructured peptides in both mitochondria and chloroplasts. The first structure of PreP from Arabidopsis thaliana refined at 2.1 Angstroms resolution shows how the 995-residue polypeptide forms a unique proteolytic chamber of more than 10,000 Angstroms(3) in which the active site resides. Although there is no visible opening to the chamber, a peptide is bound to the active site. The closed conformation places previously unidentified residues from the C-terminal domain at the active site, separated by almost 800 residues in sequence to active site residues located in the N-terminal domain. Based on the structure, a novel mechanism for proteolysis is proposed involving hinge-bending motions that cause the protease to open and close in response to substrate binding. In support of this model, cysteine double mutants designed to keep the chamber covalently locked show no activity under oxidizing conditions. The manner in which substrates are processed inside the chamber is reminiscent of the proteasome; therefore, we refer to this protein as a peptidasome.     

Targeting capacity and conservation of PreP homologues localization in mitochondria of different species

Mitochondrial presequences and other unstructured peptides are degraded inside mitochondria by presequence proteases (PrePs) identified in Arabidopsis thaliana (AtPreP), humans (hPreP), and yeast (Cym1/Mop112). The presequences of A. thaliana and human PreP are predicted to consist of 85 and 29 amino acids, respectively, whereas the Saccharomyces cerevisiae Cym1/Mop112 presequence contains only 7 residues. These differences may explain the reported targeting of homologous proteins to different mitochondrial subcompartments. Here we have investigated the targeting capacity of the PreP homologues' presequences. We have produced fusion constructs containing N-terminal portions of AtPreP(1-125), hPreP(1-69), and Cym1(1-40) coupled to green fluorescent protein (GFP) and studied their import into isolated plant, mammalian, and yeast mitochondria, followed by mitochondrial subfractionation. Whereas the AtPreP presequence has the capacity to target GFP into the mitochondrial matrix of all three species, the hPreP presequence only targets GFP to the matrix of mammalian and yeast mitochondria. The Cym1/Mop112 presequence has an overall much weaker targeting capacity and only ensures mitochondrial sorting in its host species yeast. Revisiting the submitochondrial localization of Cym1 revealed that endogenous Cym1/Mop112 is localized to the matrix space, as has been previously reported for the plant and human homologues. Moreover, complementation studies in yeast show that native AtPreP restores the growth phenotype of yeast cells lacking Cym1, demonstrating functional conservation.     

Simple sequence repeats in organellar genomes of rice: frequency and distribution in genic and intergenic regions

MOTIVATION: Simple sequence repeats (SSRs) are abundant across genomes. However, the significance of SSRs in organellar genomes of rice has not been completely understood. The availability of organellar genome sequences allows us to understand the organization of SSRs in their genic and intergenic regions. RESULTS: We have analyzed SSRs in mitochondrial and chloroplast genomes of rice. We identified 2528 SSRs in the mitochondrial genome and average 870 SSRs in the chloroplast genomes. About 8.7% of the mitochondrial and 27.5% of the chloroplast SSRs were observed in the genic region. Dinucleotides were the most abundant repeats in genic and intergenic regions of the mitochondrial genome while mononucleotides were predominant in the chloroplast genomes. The rps and nad gene clusters of mitochondria had the maximum repeats, while the rpo and ndh gene clusters of chloroplast had the maximum repeats. We identified SSRs in both organellar genomes and validated in different cultivars and species.     

Microsatellite analysis in organelle genomes of Chlorophyta

Simple Sequence Repeats (SSRs) or microsatellites constitute a significant portion of genomes however; their significance in organellar genomes has not been completely understood. The availability of organelle genome sequences allows us to understand the organization of SSRs in their genic and intergenic regions. In the present work, SSRs were identified and categorized in 14 mitochondrial and 22 chloroplast genomes of algal species belonging to Chlorophyta. Based on the study, it was observed that number of SSRs in non-coding region were more as compared to coding region and frequency of mononucleotides repeats were highest followed by dinucleotides in both mitochondrial and chloroplast genomes. It was also observed that maximum number of SSRs was found in genes encoding for beta subunit of RNA polymerase in chloroplast genomes and NADH dehydrogenase in mitochondrial genomes. This is the first and original report on whole genomes sequence analysis of organellar genomes of green algae.     

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.     

Synthetic transit peptides inhibit import and processing of mitochondrial precursor proteins

We have demonstrated that a synthetic peptide corresponding to the rat mitochondrial malate dehydrogenase (mMDH) transit peptide (TP-28) inhibits the binding of pre-mMDH to isolated mitochondria. Synthetic peptides derived from chloroplast transit peptide sequences, which have a similar net charge, did not inhibit import. In addition, this peptide (TP-28) inhibits import of ornithine transcarbamylase, another mitochondrial matrix protein, thus suggesting that common import pathways exist for both mMDH and ornithine transcarbamylase. A smaller synthetic peptide corresponding to residues 1-20 of the mMDH transit peptide (TP-20) also inhibits binding. However, several substitutions for leucine-13 in the smaller peptide relieve import inhibition, thus providing evidence that this neutral residue plays a crucial role in transit peptide binding to the mitochondrial surface. Proteolytic processing of pre-mMDH by a mitochondrial matrix fraction to both the mature and intermediate forms of mMDH was also inhibited by TP-28. The ability of synthetic peptides to inhibit distinct steps in the import of mitochondrial precursor proteins corresponds precisely to their ability to interact with the same components used by transit peptides on intact precursors. Furthermore, inhibition at multiple points along the import pathway reflects the functions of several independent structures contained within transit peptides.     

Resolution of mitochondrial and chloroplast membrane protein complexes from green leaves of potato on blue-native polyacrylamide gels

Purification of mitochondria and mitochondrial protein complexes from green tissues is often severely impaired by the presence of chloroplasts and their proteins. Here we present a method which allows analysis of respiratory protein complexes from potato leaves. The procedure includes the preparation of an organellar fraction specifically enriched in mitochondria and the separation of organellar protein complexes by blue-native polyacrylamide gel electrophoresis (BN-PAGE). For the first time mitochondrial and chloroplast protein complexes have been resolved simultaneously in a native gel. BN-PAGE allowed the separation of eleven bands, including the mitochondrial NADH-dehydrogenase, the bc1 complex and the mitochondrial F1-ATP synthase as well as the chloroplast F1-ATP synthase, the cytochrome b6f complex, the two photosystems and the light harvesting complex. The resolution of the protein complexes in the first dimension was good enough to allow identification of all subunits of individual complexes in the second dimension under denaturing conditions. Thus, BN-PAGE offers an opportunity to analyze mitochondrial and chloroplast protein complexes from a single preparation from very small amounts of tissue. The implications of our findings, for studies on protein expression and turnover in different tissues and developmental stages, are discussed.     

Function of a chloroplast SRP in thylakoid protein export.

Protein export systems derived from prokaryotes are used to transport proteins into or across the endoplasmic reticulum, the mitochondrial inner membrane, and the chloroplast thylakoid membrane. Signal recognition particle (SRP) and its receptor are essential components used exclusively for cotranslational export of endomembrane and secretory proteins to the endoplasmic reticulum in eukaryotes and export of polytopic membrane proteins to the cytoplasmic membrane in prokaryotes. An organellar SRP in chloroplasts (cpSRP) participates in cotranslational targeting of chloroplast synthesized integral thylakoid proteins. Remarkably, cpSRP is also used to posttranslationally localize a subset of nuclear encoded thylakoid proteins. Recent work has begun to reveal the basis for cpSRP's unique ability to function in co- and posttranslational protein localization, yet much is left to question. This review will attempt to highlight these advances and will also focus on the role of other soluble and membrane components that are part of this novel organellar SRP targeting pathway.