The AAA-type ATPases Pex1p and Pex6p and their role in peroxisomal matrix protein import in Saccharomyces cerevisiae

The recognition of the conserved ATP-binding domains of Pex1p, p97 and NSF led to the discovery of the family of AAA-type ATPases. The biogenesis of peroxisomes critically depends on the function of two AAA-type ATPases, namely Pex1p and Pex6p, which provide the energy for import of peroxisomal matrix proteins. Peroxisomal matrix proteins are synthesized on free ribosomes in the cytosol and guided to the peroxisomal membrane by specific soluble receptors. At the membrane, the cargo-loaded receptors bind to a docking complex and the receptor-docking complex assembly is thought to form a dynamic pore which enables the transition of the cargo into the organellar lumen. The import cycle is completed by ubiquitination- and ATP-dependent dislocation of the receptor from the membrane to the cytosol, which is performed by the AAA-peroxins. Receptor ubiquitination and dislocation are the only energy-dependent steps in peroxisomal protein import. The export-driven import model suggests that the AAA-peroxins might function as motor proteins in peroxisomal import by coupling ATP-dependent removal of the peroxisomal import receptor and cargo translocation into the organelle.     

Functional role of the AAA peroxins in dislocation of the cycling PTS1 receptor back to the cytosol

Peroxisomal import receptors bind their cargo proteins in the cytosol and target them to docking and translocation machinery at the peroxisomal membrane (reviewed in ref. 1). The receptors release the cargo proteins into the peroxisomal lumen and, according to the model of cycling receptors, they are supposed to shuttle back to the cytosol. This shuttling of the receptors has been assigned to peroxins including the AAA peroxins Pex1p and Pex6p, as well as the ubiquitin-conjugating enzyme Pex4p (reviewed in ref. 2). One possible target for Pex4p is the PTS1 receptor Pex5p, which has recently been shown to be ubiquitinated. Pex1p and Pex6p are both cytosolic and membrane-associated AAA ATPases of the peroxisomal protein import machinery, the exact function of which is still unknown. Here we demonstrate that the AAA peroxins mediate the ATP-dependent dislocation of the peroxisomal targeting signal-1 (PTS1) receptor from the peroxisomal membrane to the cytosol.     

The peroxisomal protein import machinery displays a preference for monomeric substrates

Peroxisomal matrix proteins are synthesized on cytosolic ribosomes and transported by the shuttling receptor PEX5 to the peroxisomal membrane docking/translocation machinery, where they are translocated into the organelle matrix. Under certain experimental conditions this protein import machinery has the remarkable capacity to accept already oligomerized proteins, a property that has heavily influenced current models on the mechanism of peroxisomal protein import. However, whether or not oligomeric proteins are really the best and most frequent clients of this machinery remain unclear. In this work, we present three lines of evidence suggesting that the peroxisomal import machinery displays a preference for monomeric proteins. First, in agreement with previous findings on catalase, we show that PEX5 binds newly synthesized (monomeric) acyl-CoA oxidase 1 (ACOX1) and urate oxidase (UOX), potently inhibiting their oligomerization. Second, in vitro import experiments suggest that monomeric ACOX1 and UOX are better peroxisomal import substrates than the corresponding oligomeric forms. Finally, we provide data strongly suggesting that although ACOX1 lacking a peroxisomal targeting signal can be imported into peroxisomes when co-expressed with ACOX1 containing its targeting signal, this import pathway is inefficient.     

Essential role of Mia40 in import and assembly of mitochondrial intermembrane space proteins

Mitochondria import nuclear-encoded precursor proteins to four different subcompartments. Specific import machineries have been identified that direct the precursor proteins to the mitochondrial outer membrane, inner membrane or matrix, respectively. However, a machinery dedicated to the import of mitochondrial intermembrane space (IMS) proteins has not been found so far. We have identified the essential IMS protein Mia40 (encoded by the Saccharomyces cerevisiae open reading frame YKL195w). Mitochondria with a mutant form of Mia40 are selectively inhibited in the import of several small IMS proteins, including the essential proteins Tim9 and Tim10. The import of proteins to the other mitochondrial subcompartments does not depend on functional Mia40. The binding of small Tim proteins to Mia40 is crucial for their transport across the outer membrane and represents an initial step in their assembly into IMS complexes. We conclude that Mia40 is a central component of the protein import and assembly machinery of the mitochondrial IMS.     

蛋白质的入核运送和它在基因表达中的调节作用

蛋白质进入细胞核是由蛋白质分子内部的核定位信号（nuclear localization signal, NLS）引导的.NLS蛋白首先与NLS受体结合,然后在多种胞浆因子及核孔复合物蛋白的作用下穿过核孔、转位入核.蛋白质上存在NLS并不一定总能够引导蛋白质入核.当NLS被修饰或遮掩时,它们便不能被核转运装置所识别.因而,NLS的遮掩被解除之前,蛋白质一直被扣留在胞浆中.以调节转录因子的入核运送来控制转录因子的活性是基因表达调节的一个新概念,也是细胞生长和分化的另一水平的调节.     

Chloroplast precursor proteins compete to form early import intermediates in isolated pea chloroplasts

In order to ascertain whether there is one site for the import of precursor proteins into chloroplasts or whether different precursor proteins are imported via different import machineries, chloroplasts were incubated with large quantities of the precursor of the 33 kDa subunit of the oxygen-evolving complex (pOE33) or the precursor of the light-harvesting chlorophyll a/b-binding protein (pLHCP) and tested for their ability to import a wide range of other chloroplast precursor proteins. Both pOE33 and pLHCP competed for import into chloroplasts with precursors of the stromally-targeted small subunit of Rubisco (pSSu), ferredoxin NADP(+) reductase (pFNR) and porphobilinogen deaminase; the thylakoid membrane proteins LHCP and the Rieske iron-sulphur protein (pRieske protein); ferrochelatase and the gamma subunit of the ATP synthase (which are both associated with the thylakoid membrane); the thylakoid lumenal protein plastocyanin and the phosphate translocator, an integral membrane protein of the inner envelope. The concentrations of pOE33 or pLHCP required to cause half-maximal inhibition of import ranged between 0.2 and 4.9 microM. These results indicate that all of these proteins are imported into the chloroplast by a common import machinery. Incubation of chloroplasts with pOE33 inhibited the formation of early import intermediates of pSSu, pFNR and pRieske protein.     

Cytosol-dependent peroxisomal protein import in a permeabilized cell system

Using streptolysin-O (SLO) we have developed a permeabilized cell system retaining the competence to import proteins into peroxisomes. We used luciferase and albumin conjugated with a peptide ending in the peroxisomal targeting sequence, SKL, to monitor the import of proteins into peroxisomes. After incubation with SLO-permeabilized cells, these exogenous proteins accumulated within catalase-containing vesicles. The import was strictly signal dependent and could be blocked by a 10-fold excess of peptide containing the SKL-targeting signal, while a control peptide did not affect the import. Peroxisomal accumulation of proteins was time and temperature dependent and required ATP hydrolysis. Dissipation of the membrane potential did not alter the import efficiency. GTP-hydrolyzing proteins were not required for peroxisomal protein targeting. Depletion of endogenous cytosol from permeabilized cells abolished the competence to import proteins into peroxisomes but import was reconstituted by the addition of external cytosol. We present evidence that cytosol contains factors with SKL-specific binding sites. The activity of cytosol is insensitive to N- ethylmaleimide (NEM) treatment, while the cells contain NEM-sensitive membrane-bound or associated proteins which are involved in the import machinery. The cytosol dependence and NEM-sensitivity of peroxisomal protein import should facilitate the purification of proteins involved in the import of proteins into peroxisomes.     

The plastid-encoded protein Orf2971 is required for protein translocation and chloroplast quality control

Photosynthesis and the biosynthesis of many important metabolites occur in chloroplasts. In these semi-autonomous organelles, the chloroplast genome encodes approximately 100 proteins. The remaining chloroplast proteins, close to 3,000, are encoded by nuclear genes whose products are translated in the cytosol and imported into chloroplasts. However, there is still no consensus on the composition of the protein import machinery including its motor proteins and on how newly imported chloroplast proteins are refolded. In this study, we have examined the function of orf2971, the largest chloroplast gene of Chlamydomonas reinhardtii. The depletion of Orf2971 causes the accumulation of protein precursors, partial proteolysis and aggregation of proteins, increased expression of chaperones and proteases, and autophagy. Orf2971 interacts with the TIC (translocon at the inner chloroplast envelope) complex, catalyzes ATP (adenosine triphosphate) hydrolysis, and associates with chaperones and chaperonins. We propose that Orf2971 is intimately connected to the protein import machinery and plays an important role in chloroplast protein quality control.

Repression of Orf2971 induces accumulation of chloroplast precursor proteins and impaired chloroplast quality indicating that Orf2971 is required for protein import and chloroplast quality control.

IN A NUTSHELL Background: The chloroplast is an important bioreactor as well as a photosynthetic site. Approximately 3,000 plastid proteins encoded in the nucleus are translocated into the chloroplast envelope via the TOC (translocon at the outer chloroplast envelope) and TIC machineries. Most nucleus-encoded preproteins that enter the plastid are unfolded as they traverse the TOC–TIC import complexes. To prevent these unfolded or misfolded proteins from causing chloroplast damage, a quality control mechanism comprising molecular chaperones and proteases ensures that all polypeptides entering chloroplasts are either correctly folded or degraded. However, there is still no consensus on the TIC complex’s components, motor proteins, or mechanism for refolding proteins entering the chloroplast. Question: What is the precise function of each of the proteins in the TIC complex? What is the composition of the chloroplast protein import machinery motor? How are the newly imported chloroplast proteins refolded and assembled into functional complexes? Findings: We found that Orf2971, encoded by the largest gene in the Chlamydomonas reinhardtii chloroplast genome and proposed to be an ortholog of Ycf2, is directly associated with the protein import machinery and plays a crucial role in ensuring the quality of proteins targeted to the chloroplast. Orf2971 deficiency induces protein precursor accumulation, partial proteolysis and protein aggregation, increased expression of chaperones and proteases, and autophagy. We hypothesize that Orf2971 is intimately linked to the protein import machinery and plays a critical role in chloroplast protein quality control. Next steps: The next challenge is to identify the sorting components associated with this complex on the stromal side. Furthermore, additional experimental evidence is required to investigate the relationship between different import machineries, including the analysis of the accumulation of precursor proteins in the various import mutants.     

The Mitochondrial Protein Import Pathway: Are Precursors Imported through Membrane Channels?

Mitochondrial biogenesis requires the import of hundreds of different proteins from the cytosol. Protein import into mitochondria is a multistep pathway that includes recognition of precursor proteins by machinery both in the cytoplasm and on the mitochondrial surface, translocation of the precursor across one or both mitochondrial membranes, and folding of the protein after its import into the organelle. Over the past several years, many components of the import machinery have been identified using both biochemical and genetic methods. Recently, significant progress has been made determining the function of some of these import proteins. One purpose of this minireview is to summarize our current understanding of the import pathway, and to introduce the topics of the minireviews that will follow. The other goal of this minireview is to discuss recent findings suggesting that proteins are translocated across both the mitochondrial inner and outer membranes through aqueous channels.     

Switch from capsid protein import to adenovirus assembly by cleavage of nuclear transport signals

Replication and assembly of adenovirus occurs in the nucleus of infected cells, requiring the nuclear import of all viral structural proteins. In this report we show that nuclear import of the major capsid protein, hexon, is mediated by protein VI, a structural protein located underneath the 12 vertices of the adenoviral capsid. Our data indicate that protein VI shuttles between the nucleus and the cytoplasm and that it links hexon to the nuclear import machinery via an importin alpha/beta-dependent mechanism. Key nuclear import and export signals of protein VI are located in a short C-terminal segment, which is proteolytically removed during virus maturation. The removal of these C-terminal transport signals appears to trigger a functional transition in protein VI, from a role in supporting hexon nuclear import to a structural role in virus assembly.     

Ubp15p, a ubiquitin hydrolase associated with the peroxisomal export machinery

Peroxisomal matrix protein import is facilitated by cycling receptors shuttling between the cytosol and the peroxisomal membrane. One crucial step in this cycle is the ATP-dependent release of the receptors from the peroxisomal membrane. This step is facilitated by the peroxisomal AAA (ATPases associated with various cellular activities) proteins Pex1p and Pex6p with ubiquitination of the receptor being the main signal for its export. Here we report that the AAA complex contains dislocase as well as deubiquitinating activity. Ubp15p, a ubiquitin hydrolase, was identified as a novel constituent of the complex. Ubp15p partially localizes to peroxisomes and is capable of cleaving off ubiquitin moieties from the type I peroxisomal targeting sequence (PTS1) receptor Pex5p. Furthermore, Ubp15p-deficient cells are characterized by a stress-related PTS1 import defect. The results merge into a picture in which removal of ubiquitin from the PTS1 receptor Pex5p is a specific event and might represent a vital step in receptor recycling.     

Zinc-dependent intermembrane space proteins stimulate import of carrier proteins into plant mitochondria

Mitochondrial inner membrane carrier proteins are imported into mitochondria from yeast, fungi and mammals by specific machinery, some components of which are distinct from those utilized by other proteins. Import of two different carriers into plant mitochondria showed that one contains a cleavable presequence which was processed during import, while the other imported in a valinomycin-sensitive manner without processing. Mild osmotic shock of mitochondria released intermembrane space (IMS) components and impaired carrier protein import. Adding back the released IMS proteins as a concentrate in the presence of micromolar ZnCl2 stimulated carrier import into IMS-depleted mitochondria, but did not stimulate import of a non-carrier control precursor protein, the alternative oxidase. Anion-exchange separation of IMS components before addition to IMS-depleted mitochondria revealed a correlation between several 9-10 kDa proteins and stimulation of carrier import. MS/MS sequencing of these proteins identified them as plant homologues of the yeast zinc-finger carrier import components Tim9 and Tim10. Stimulation of import was dependent on either Zn2+ or Cd2+ and inhibited by both N-ethylmalamide (NEM) and a divalent cation chelator, consistent with a functional requirement for a zinc finger protein. This represents direct functional evidence for a distinct carrier import pathway in plant mitochondria, and provides a tool for determining the potential function of other IMS proteins associated with protein import.     

Defective mitochondrial protein translocation precludes normal Caenorhabditis elegans development

We demonstrate biochemically that the genes identified by sequence similarity as orthologs of the mitochondrial import machinery are functionally conserved in Caenorhabditis elegans. Specifically, tin-9.1 and tin-10 RNA interference (RNAi) treatment of nematodes impairs import of the ADP/ATP carrier into isolated mitochondria. Developmental phenotypes are associated with gene knock-down of the mitochondrial import components. RNAi of tomm-7 and ddp-1 resulted in mitochondria with an interconnected morphology in vivo, presumably due to defects in the assembly of outer membrane fission/fusion components. RNAi of the small Tim proteins TIN-9.1, TIN-9.2, and TIN-10 resulted in a small body size, reduced number of progeny produced, and partial embryonic lethality. An additional phenotype of the tin-9.2(RNAi) animals is defective formation of the somatic gonad. The biochemical demonstration that the protein import activity is reduced, under the same conditions that yield the defects in specific tissues and lethality in a later generation, suggests that the developmental abnormalities observed are a consequence of defects in mitochondrial inner membrane biogenesis.     

Covalent Label Transfer between Peroxisomal Importomer Components Reveals Export-driven Import Interactions

Peroxisomes are vital metabolic organelles found in almost all eukaryotic organisms, and they rely exclusively on import of their matrix protein content from the cytosol. In vitro import of proteins into isolated peroxisomal fractions has provided a wealth of knowledge on the import process. However, the common method of protease protection garnered no information on the import of an N-terminally truncated PEX5 (PEX5C) receptor construct or peroxisomal malate dehydrogenase 1 (pMDH1) cargo protein into sunflower peroxisomes because of high degrees of protease susceptibility or resistance, respectively. Here we present a means for analysis of in vitro import through a covalent biotin label transfer and employ this method to the import of PEX5C. Label transfer demonstrates that the PEX5C construct is monomeric under the conditions of the import assay. This technique was capable of identifying the PEX5-PEX14 interaction as the first interaction of the import process through competition experiments. Labeling of the peroxisomal protein import machinery by PEX5C demonstrated that this interaction was independent of added cargo protein, and, strikingly, the interaction between PEX5C and the import machinery was shown to be ATP-dependent. These important mechanistic insights highlight the power of label transfer in studying interactions, rather than proteins, of interest and demonstrate that this technique should be applied to future studies of peroxisomal in vitro import.     

Protein import into chloroplasts

Most chloroplastic proteins are encoded in the nucleus, synthesized on cytosolic ribosomes and subsequently imported into the organelle. In general, proteins destined for the chloroplast are synthesized as precursor proteins with a cleavable N-terminal presequence that mediates routing to the inside of the chloroplast. These precursor proteins have to be targeted to the correct organellar membrane surface after their release from the ribosome and furthermore they have to be maintained in a conformation suitable for translocation across the two envelope membranes. Recognition and import of most chloroplastic precursor proteins are accomplished by a jointly used translocation apparatus. Different but complementary studies of several groups converged recently in the identification of the outer envelope proteins OEP86, OEP75, OEP70 (a Hsp 70-related protein), OEP34, and of the inner envelope protein IEP110 as components of this translocation machinery. None of these proteins, except for OEP70, shows any homology to components of other protein translocases. The plastid import machinery thus seems to be an original development in evolution. Following translocation into the organelle, chloroplastic proteins are sorted to their suborganellar destination, i.e., the inner envelope membrane, the thylakoid membrane, and the thylakoid lumen. This structural and evolutionary complexity of chloroplasts is reflected by a variety of routing mechanisms by which proteins reach their final location once inside the organelle. This review will focus on recent advances in the identification of components of the chloroplastic protein import machinery, and new insights into the pathways of inter-and intraorganellar sorting.     

The cleavable pre-sequence of an imported chloroplast protein directs attached polypeptides into yeast mitochondria

The cleavable pre-sequences of imported chloroplast and mitochondrial proteins have several features in common. This structural similarity prompted us to test whether a chloroplast pre-sequence (`transit peptide') can also be decoded by the mitochondrial import machinery. In the green alga, Chlamydomonas reinhardtii, the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) (a chloroplast protein) is nuclear-encoded and synthesized in the cytosol with a transient pre-sequence of 45 residues. The 31 amino-terminal residues of this chloroplast pre-sequence were fused to mouse dihydrofolate reductase (a cytosolic protein) and to yeast cytochrome oxidase subunit IV (an imported mitochondrial protein) from which the authentic pre-sequence had been removed. The chloroplast pre-sequence transported both attached proteins into the yeast mitochondrial matrix or inner membrane, although it functioned less efficiently than an authentic mitochondrial pre-sequence. We conclude that mitochondrial and chloroplast pre-sequences perform their function by a similar mechanism.     

Getting a camel through the eye of a needle: the import of folded proteins by peroxisomes

Peroxisomes are a family of organelles which have many unusual features. They can arise de novo from the endoplasmic reticulum by a still poorly characterized process, yet possess a unique machinery for the import of their matrix proteins. As peroxisomes lack DNA, their function, which is highly variable and dependent on developmental and/or environmental conditions, is determined by the post‐translational import of specific metabolic enzymes in folded or oligomeric states. The two classes of matrix targeting signals for peroxisomal proteins [PTS1 (peroxisomal targeting signal 1) and PTS2] are recognized by cytosolic receptors [PEX5 (peroxin 5) and PEX7 respectively] which escort their cargo proteins to, or possibly across, the peroxisome membrane. Although the membrane translocation mechanism remains unclear, it appears to be driven by thermodynamically favourable binding interactions. Recycling of the receptors from the peroxisome membrane requires ATP hydrolysis for two linked processes: ubiquitination of PEX5 (and the PEX7 co‐receptors in yeast) and the function of two peroxisome‐associated AAA (ATPase associated with various cellular activities) ATPases, which play a role in recycling or turnover of the ubiquitinated receptors. This review summarizes and integrates recent findings on peroxisome matrix protein import from yeast, plant and mammalian model systems, and discusses some of the gaps in our understanding of this remarkable protein transport system.     

The effect of amino acid-modifying reagents on chloroplast protein import and the formation of early import intermediates

In order to identify functionally important amino acid residues in the chloroplast protein import machinery, chloroplasts were preincubated with amino-acid-modifying reagents and then allowed to import or form early import intermediates with precursor proteins. Incubation of chloroplasts with N-ethyl maleimide, diethyl pyrocarbonate, phenylglyoxal, 4,4'-di-isothiocyanatostilbene 2,2'-disulphonic acid (DIDS), dicyclohexylcarbodiimide (DCCD), and 1-ethyl- 3-dimethylaminopropylcarbodiimide (EDC) inhibited both import and formation of early import intermediates with precursor proteins by chloroplasts. This suggests that one or more of the binding components of the chloroplast protein import machinery contains functionally important solvent-exposed cysteine, histidine, arginine, and aspartate/glutamate residues, as well as functionally important lysine and aspartate/ glutamate residues in a hydrophobic environment.     

Ancestral and derived protein import pathways in the mitochondrion of Reclinomonas americana

The evolution of mitochondria from ancestral bacteria required that new protein transport machinery be established. Recent controversy over the evolution of these new molecular machines hinges on the degree to which ancestral bacterial transporters contributed during the establishment of the new protein import pathway. Reclinomonas americana is a unicellular eukaryote with the most gene-rich mitochondrial genome known, and the large collection of membrane proteins encoded on the mitochondrial genome of R. americana includes a bacterial-type SecY protein transporter. Analysis of expressed sequence tags shows R. americana also has components of a mitochondrial protein translocase or "translocase in the inner mitochondrial membrane complex." Along with several other membrane proteins encoded on the mitochondrial genome Cox11, an assembly factor for cytochrome c oxidase retains sequence features suggesting that it is assembled by the SecY complex in R. americana. Despite this, protein import studies show that the RaCox11 protein is suited for import into mitochondria and functional complementation if the gene is transferred into the nucleus of yeast. Reclinomonas americana provides direct evidence that bacterial protein transport pathways were retained, alongside the evolving mitochondrial protein import machinery, shedding new light on the process of mitochondrial evolution.     

Translocation of mitochondrial inner-membrane proteins: conformation matters

Most of the mitochondrial inner-membrane proteins are generated without a presequence and their targeting depends on inadequately defined internal segments. Despite the numerous components of the import machinery identified by proteomics, the properties of hydrophobic import substrates remain poorly understood. Recent studies support several principles for these membrane proteins: first, they become organized into partially assembled forms within the translocon; second, they present noncontiguous targeting signals; and third, they induce conformational changes in translocase subunits, thereby mediating "assembly on demand" of the import machinery. It is possible that the energy needed for these proteins to pass across the outer membrane, to travel through the intermembrane space and to target the inner-membrane surface is provided by conformational changes involving import components that seem to have natively unfolded structures. Such structural malleability might render some of the translocase subunits more adept at driving the protein import process.