Transport of microinjected proteins into peroxisomes of mammalian cells: inability of Zellweger cell lines to import proteins with the SKL tripeptide peroxisomal targeting signal.

Previous work has shown that the firefly (Photinus pyralis) luciferase contains a C-terminal peroxisomal targeting signal consisting of the tripeptide Ser-Lys-Leu. This report describes the microinjection of two proteins, (i) luciferase and (ii) albumin conjugated to a peptide ending in the sequence Ser-Lys-Leu, into mammalian cells grown in tissue culture. Following microinjection, incubation of the cells at 37 degrees C resulted in peroxisomal transport of these exogenous proteins into catalase-containing vesicles. The translocation was both time and temperature dependent. The transport could be inhibited by coinjection of synthetic peptides bearing various peroxisomal targeting signal motifs. These proteins could be transported into peroxisomes in normal human fibroblast cell lines but not in cell lines derived from patients with Zellweger syndrome. These results demonstrate that microinjection of peroxisomal proteins yields an authentic in vivo system with which to study peroxisomal transport. Furthermore, these results reveal that the process of peroxisomal transport does not involve irreversible modification of the protein, that artificial hybrid substrates can be transported and used as tools to study peroxisomal transport, and that the defect in Zellweger syndrome is indeed the inability to transport proteins containing the Ser-Lys-Leu targeting signal into the peroxisomal lumen.     

The conserved fission complex on peroxisomes and mitochondria

Peroxisomes are eukaryotic organelles highly versatile and dynamic in content and abundance. Plant peroxisomes mediate various metabolic pathways, a number of which are completed sequentially in peroxisomes and other subcellular organelles, including mitochondria and chloroplasts. To understand how peroxisomal dynamics contribute to changes in plant physiology and adaptation, the multiplication pathways of peroxisomes are being dissected. Research in Arabidopsis thaliana has identified several evolutionarily conserved families of proteins in peroxisome division. These include five PEROXIN11 proteins (PEX11a to -e) that induce peroxisome elongation and the fission machinery, which is composed of three dynamin-related proteins (DRP3A, -3B and -5B) and DRP''s membrane receptor, FISSION1 (FIS1A and -1B). While the function of PEX11 is restricted to peroxisomes, the fission factors are more promiscuous. DRP3 and FIS1 proteins are shared between peroxisomes and mitochondria, and DRP5B plays a dual role in the division of chloroplasts and peroxisomes. Analysis of the Arabidopsis genome suggests that higher plants may also contain functional homologs of the yeast Mdv1/Caf4 proteins, adaptor proteins that link DRPs to FIS1 on the membrane of both peroxisomes and mitochondria. Sharing a conserved fission machine between these metabolically linked subcellular compartments throughout evolution may have some biological significance.Key words: Arabidopsis, peroxisomal and mitochondrial division, dynamin-related protein (DRP), FISSION1 (FIS1), mitochondrial division 1 (Mdv1), CCR4p-associated factor 4 (Caf4)Peroxisomes are single membrane-delimited organelles involved in a variety of metabolic pathways essential to development.¹ Plant peroxisomes participate in processes such as lipid mobilization, photorespiration, detoxification, hormone biosynthesis and metabolism, and plant-pathogen interaction.^2,3 A number of these metabolic functions, such as photorespiration, fatty acid metabolism and jasmonic acid biosynthesis, are accomplished through the cooperative efforts of peroxisomes and other subcellular compartments, such as mitochondria and chloroplasts.^3–5 The function, morphology and abundance of peroxisomes can vary depending on the organism, cell type, developmental stage and prevailing environmental conditions in which the organism resides.^6,7 It is now believed that in addition to budding from the endoplasmic reticulum (ER), peroxisomes also multiply from pre-existing peroxisomes via division, going through steps including peroxisome elongation/tubulation, membrane constriction and fission.^7,8In the reference plant Arabidopsis thaliana, three evolutionarily conserved families of proteins have been identified as key components of the peroxisome division apparatus. Five integral membrane proteins, named PEX11a to -e, are mainly responsible for inducing the elongation and tubulation of peroxisomes in the early stage of peroxisome division.^9–11 DRP3A and DRP3B are members of a dynamin-related protein family that powers the fission of membranes and FIS1A and FIS1B are homologous proteins believed to anchor the DRP proteins to the membrane.^12–19 Similar to their counterparts in yeasts and mammals, DRP3 and FIS1 are shared by the fission machineries of peroxisomes and mitochondria.^12–19 We recently reported the unexpected finding that DRP5B, a plant/algal-specific DRP distantly related to the DRP3 proteins and originally discovered for its function in chloroplast division, is also involved in the division of peroxisomes. Using co-immunoprecipitation (co-IP) and bimolecular fluorescence complementation (BiFC) assays, we further demonstrated that DRP5B and the two DRP3 proteins can homo- and hetero-dimerize and each DRP can form a complex with FIS1A and/or FIS1B and most of the Arabidopsis PEX11 isoforms.²⁰ These results together demonstrate that, despite their distinct evolutionary origins, structures and functions, peroxisomes, mitochondria and chloroplasts use some of the same factors for fission. These data also revealed that, like in yeasts and mammals, the FIS1-DRP complex exits on peroxisomes and mitochondria in plants.DRP5B, a DRP unique in the plant and photosynthetic algae lineages, seems to be the sole component shared by the division of chloroplasts and peroxisomes.²⁰ However, both FIS1 and DRP are found to be required for the division of peroxisomes and mitochondria throughout eukaryotic evolution,^21,22 prompting the question: to what extent is the FIS1-DRP complex conserved among diverse species? In the yeast Saccharomyces cerevisiae, this fission complex also contains an adaptor encoded by two homologous WD40 proteins, Mdv1 and Caf4, which are partially redundant in function with Mdv1 playing the major role. Mdv1 and Caf4 share an N-terminal extension (NTE) domain with two α-helices, a middle coiled-coil domain (CC) and C-terminal WD40 repeat. Both proteins use the NTE to interact with the tetratricopeptide repeat (TPR) domain-containing N-terminus of Fis1, the CC domain to dimerize and the C-terminal WD40 repeat to interact with and recruit the DRP protein, Dnm1.^23,24 The Hansenula polymorpha Mdv1 (Hp Mdv1) also has a dual function in the division of peroxisomes and mitochondria.²⁵ In addition, a Mdv1/Caf4 homolog, Mda1, was identified from the primitive red algae Cyanidioschyzon merolae and found to be involved at least in mitochondrial fission.²⁶ However, higher eukaryotes do not seem to have obvious homologs of Mdv1/Caf4. For example, mammals contain Fis1 and Drp (called DLP1 or Drp1) but no apparent homologs to Mdv1 and Caf4. Instead, a metazoan-specific tail-anchored protein, Mitochondrial Fission Factor (Mff), was recently found to regulate the fission of mitochondria and peroxisomes in a similar manner to Fis1. Mff is essential in recruiting Drp1, at least in mitochondrial division, yet it functions in a Fis1-independent pathway.^27,28To determine whether plants contain structural or functional homologs of Mdv1 and Caf4, we performed blast searches of the Arabidopsis genome, which resulted in the retrieval of ∼300 WD40 proteins. However, just like the search results from mammals, none of these proteins show significant sequence similarity with Mdv1 and Caf4 beyond the WD40 repeats. To identify proteins with similar domain structures with Mdv1/Caf4, we further analyzed these WD40 proteins, using the online Simple Modular Architecture Research Tool (smart.embl-heidelberg.de/). After eliminating proteins apparently inappropriate to be part of this complex, such as kinases and proteins with drastically distinct domain organizations despite of having both WD40 repeats and CC domains, we were able to narrow down to eight proteins. These proteins, which are encoded by At1g04510, At2g32950, At2g33340, At3g18860, At4g05410, At4g21130, At5g50230 and At5g67320, respectively, each contain a central CC domain in addition to the WD40 repeat region and are ranging from 450 to 900 amino acids in length (Fig. 1A). Subcellular localization studies will need to be performed to determine whether some of these proteins are associated with peroxisomes and mitochondria. If such a WD40 protein is proven to be part of the FIS1-DRP complex in Arabidopsis, it will be important to determine whether it simply acts as an adaptor or it also plays other roles, such as to promote and maintain the active structure and conformation of DRP3A/3B at the division site (Fig. 1B). Consistent with the latter scenario, it was found that Sc Mdv1 accumulates at the division sites after Dnm1 assembles and that the mammalian Fis1 and Drp1 proteins physically interact.^29,30 Peroxisomes and mitochondria are functionally linked in a number of metabolic pathways. For example, in plants, they act cooperatively in important processes such as fatty acid metabolism and photorespiration.³ An interesting question to address in the future is whether sharing such a conserved fission machine between peroxisomes and mitochondria throughout evolution has critical biological consequences.Open in a separate windowFigure 1Domain structure of Mdv1/Caf4 and their homologs or putative homologs. (A) Domain structure of Sc Mdv1 and Sc Caf4 from S. cerevisiae, their homologs from H. polymorpha and C. merolae, and the eight Arabidopsis proteins with similar domain organization. Grey boxes indicate the CC domain and black boxes are Wd40 repeats. (B) The putative FIS1-WD40-DRP complex in Arabidopsis. CC, coiled-coil; NTE, N-terminal extension; TPR, tetratricopeptide repeat; TMD, transmembrane domain.     

The carboxyl-terminal tripeptide Ala-Lys-Ile is essential for targeting Candida tropicalis trifunctional enzyme to yeast peroxisomes.

The gene encoding Candida tropicalis peroxisomal trifunctional enzyme, hydratase-dehydrogenase-epimerase (HDE), was expressed in both Candida albicans and Saccharomyces cerevisiae. The cellular location of HDE was determined by subcellular fractionation followed by Western blot analysis of peroxisomal and cytosolic fractions using antiserum specific for HDE. HDE was found to be exclusively targeted to and imported into peroxisomes in both heterologous expression systems. Deletion and mutational analyses were used to determine the regions within HDE which are essential for its targeting to peroxisomes. Deletion of a carboxyl-terminal tripeptide Ala-Lys-Ile completely abolished targeting of HDE to peroxisomes, whereas large internal deletions of HDE (amino acids 38-353 or 395-731) had no effect on HDE targeting to peroxisomes in either yeast. This tripeptide is similar to, but distinct from, other tripeptide peroxisomal targeting sequences (PTSs) as identified in peroxisomal firefly luciferase and four mammalian peroxisomal proteins. Substitutions within the carboxyl-terminal tripeptide (Ala----Gly and Lys----Gln) supported targeting of HDE to peroxisomes of C. albicans but not of S. cerevisiae. This is the first detailed analysis of the peroxisomal targeting signal in a yeast peroxisomal protein.     

Import of proteins into peroxisomes.

Peroxisomes are organelles that confine an important set of enzymes within their single membrane boundaries. In man, a wide variety of genetic disorders is caused by loss of peroxisome function. In the most severe cases, the clinical phenotype indicates that abnormalities begin to appear during embryological development. In less severe cases, the quality of life of adults is affected. Research on yeast model systems has contributed to a better understanding of peroxisome formation and maintenance. This framework of knowledge has made it possible to understand the molecular basis of most of the peroxisome biogenesis disorders. Interestingly, most peroxisome biogenesis disorders are caused by a failure to target peroxisomal proteins to the organellar matrix or membrane, which classifies them as protein targeting diseases. Here we review recent fundamental research on peroxisomal protein targeting and discuss a few burning questions in the field concerning the origin of peroxisomes.     

A synthesis approach to understanding repeated peptides conserved in mineralization proteins

We created artificial proteins that contained repeats of a short peptide motif, Asn-Gly-Asx. In nature this motif is repeated within shell proteins as an idiosyncratic domain, while in vitro it has been shown to suppress calcification. The motif was embedded within peptide sequences that did or did not have the ability to form secondary structures, which provided the motif with a variety of physicochemical properties. Although a short synthetic peptide containing the motif did not inhibit calcification in vitro, some of the artificial proteins carrying repeats of the motif did show robust suppression of calcification. Artificial proteins lacking the motif did not exhibit suppressive activity. Likewise, one construct containing multiple repeats of the motifs also did not exert an inhibitory effect on calcification. Apparently, carrying the Asn-Gly-Asx motif is not, by itself, sufficient for expression of its cryptic activity; instead, certain physicochemical properties of the polypeptides mediate its manifestation. We anticipate that syntheses using "motif programming", such as the one described here, will shed light on the origin of repetitive sequences as well as on the evolution of biomineralization proteins.     

Caenorhabditis elegans has a single pathway to target matrix proteins to peroxisomes

All eukaryotes so far studied, including animals, plants, yeasts and trypanosomes, have two pathways to target proteins to peroxisomes. These two pathways are specific for the two types of peroxisome targeting signal (PTS) present on peroxisomal matrix proteins. Remarkably, the complete genome sequence of Caenorhabditis elegans lacks the genes encoding proteins specific for the PTS2 targeting pathway. Here we show, by expression of green fluorescent protein (GFP) reporters for both pathways, that the PTS2 pathway is indeed absent in C. elegans. Lack of this pathway in man causes severe disease due to mislocalization of PTS2-containing proteins. This raises the question as to how C. elegans has accommodated the absence of the PTS2 pathway. We found by in silico analysis that C. elegans orthologues of PTS2-containing proteins have acquired a PTS1. We propose that switching of targeting signals has allowed the PTS2 pathway to be lost in the phylogenetic lineage leading to C. elegans.     

AraPerox. A database of putative Arabidopsis proteins from plant peroxisomes

To identify unknown proteins from plant peroxisomes, the Arabidopsis genome was screened for proteins with putative major or minor peroxisome targeting signals type 1 or 2 (PTS1 or PTS2), as defined previously (Reumann S [2004] Plant Physiol 135: 783-800). About 220 and 60 proteins were identified that carry a putative PTS1 or PTS2, respectively. To further support postulated targeting to peroxisomes, several prediction programs were applied and the putative targeting domains analyzed for properties conserved in peroxisomal proteins and for PTS conservation in homologous plant expressed sequence tags. The majority of proteins with a major PTS and medium to high overall probability of peroxisomal targeting represent novel nonhypothetical proteins and include several enzymes involved in beta-oxidation of unsaturated fatty acids and branched amino acids, and 2-hydroxy acid oxidases with a predicted function in fatty acid alpha-oxidation, as well as NADP-dependent dehydrogenases and reductases. In addition, large protein families with many putative peroxisomal isoforms were recognized, including acyl-activating enzymes, GDSL lipases, and small thioesterases. Several proteins are homologous to prokaryotic enzymes of a novel aerobic hybrid degradation pathway for aromatic compounds and proposed to be involved in peroxisomal biosynthesis of plant hormones like jasmonic acid, auxin, and salicylic acid. Putative regulatory proteins of plant peroxisomes include protein kinases, small heat shock proteins, and proteases. The information on subcellular targeting prediction, homology, and in silico expression analysis for these Arabidopsis proteins has been compiled in the public database AraPerox to accelerate discovery and experimental investigation of novel metabolic and regulatory pathways of plant peroxisomes.     

A conserved tripeptide in CNG and HCN channels regulates ligand gating by controlling C-terminal oligomerization

Cyclic nucleotides directly enhance the opening of the tetrameric CNG and HCN channels, although the mechanism remains unclear. We examined why HCN and certain CNG subunits form functional homomeric channels, whereas other CNG subunits only function in heteromeric channels. The "defect" in the CNGA4 subunit that prevents its homomeric expression was localized to its C-linker, which connects the transmembrane domain to the binding domain and contains a tripeptide that decreases the efficacy of ligand gating. Remarkably, replacement of the homologous HCN tripeptide with the CNGA4 sequence transformed cAMP into an inverse agonist that inhibits HCN channel opening. Using analytical ultracentrifugation, we identified the structural basis for this gating switch: whereas cAMP normally enhances the assembly of HCN C-terminal domains into a tetrameric gating ring, inclusion of the CNGA4 tripeptide reversed this action so that cAMP now causes gating ring disassembly. Thus, ligand gating depends on the dynamic oligomerization of C-terminal binding domains.     

Hrs sorts ubiquitinated proteins into clathrin-coated microdomains of early endosomes

After endocytosis, some membrane proteins recycle from early endosomes to the plasma membrane whereas others are transported to late endosomes and lysosomes for degradation. Conjugation with the small polypeptide ubiquitin is a signal for lysosomal sorting. Here we show that the hepatocyte growth factor-regulated tyrosine kinase substrate, Hrs, is involved in the endosomal sorting of ubiquitinated membrane proteins. Hrs contains a clathrin-binding domain, and by electron microscopy we show that Hrs localizes to flat clathrin lattices on early endosomes. We demonstrate that Hrs binds directly to ubiquitin by way of a ubiquitin-interacting motif (UIM), and that ubiquitinated proteins localize specifically to Hrs- and clathrin-containing microdomains. Whereas endocytosed transferrin receptors fail to colocalize with Hrs and rapidly recycle to the cell surface, transferrin receptors that are fused to ubiquitin interact with Hrs, localize to Hrs- and clathrin-containing microdomains and are sorted to the degradative pathway. Overexpression of Hrs strongly and specifically inhibits recycling of ubiquitinated transferrin receptors by a mechanism that requires a functional UIM. We conclude that Hrs sorts ubiquitinated membrane proteins into clathrin-coated microdomains of early endosomes, thereby preventing their recycling to the cell surface.     

Importance of sequences adjacent to the terminal tripeptide in the import of a peroxisomal Candida tropicalis protein in plant peroxisomes

 The peroxisome targeting signal (PTS) required for import of the rat acyl-CoA oxidase (AOX; EC 1.3.3.6) and the Candida tropicalis multifunctional protein (MFP) in plant peroxisomes was assessed in transgenic Arabidopsis thaliana (L.) Heynh. The native rat AOX accumulated in peroxisomes in A. thaliana cotyledons and targeting was dependent on the presence of the C-terminal tripeptide S-K-L. In contrast, the native C. tropicalis MFP, containing the consensus PTS sequence A-K-I was not targeted to plant peroxisomes. Modification of the carboxy terminus to the S-K-L tripeptide also failed to deliver the MFP to peroxisomes while addition of the last 34 amino acids of the Brassica napus isocitrate lyase, containing the terminal tripeptide S-R-M, enabled import of the fusion protein into peroxisomes. These results underline the influence of the amino acids adjacent to the terminal tripeptide of the C. tropicalis MFP on peroxisomal targeting, even in the context of a protein having a consensus PTS sequence S-K-L. Received: 19 July 1999 / Accepted: 19 February 2000     

Import of stably folded proteins into peroxisomes.

By virtue of their synthesis in the cytoplasm, proteins destined for import into peroxisomes are obliged to traverse the single membrane of this organelle. Because the targeting signal for most peroxisomal matrix proteins is a carboxy-terminal tripeptide sequence (SKL or its variants), these proteins must remain import competent until their translation is complete. We sought to determine whether stably folded proteins were substrates for peroxisomal import. Prefolded proteins stabilized with disulfide bonds and chemical cross-linkers were shown to be substrates for peroxisomal import, as were mature folded and disulfide-bonded IgG molecules containing the peroxisomal targeting signal. In addition, colloidal gold particles conjugated to proteins bearing the peroxisomal targeting signal were translocated into the peroxisomal matrix. These results support the concept that proteins may fold in the mammalian cytosol, before their import into the peroxisome, and that protein unfolding is not a prerequisite for peroxisomal import.     

A conserved interaction with the chromophore of fluorescent proteins

The chromophore of fluorescent proteins, including the green fluorescent protein (GFP), contains a highly conjugated imidazolidinone ring. In many fluorescent proteins, the carbonyl group of the imidazolidinone ring engages in a hydrogen bond with the side chain of an arginine residue. Prior studies have indicated that such an electrophilic carbonyl group in a protein often accepts electron density from a main-chain oxygen. A survey of high-resolution structures of fluorescent proteins indicates that electron lone pairs of a main-chain oxygen-Thr62 in GFP-donate electron density into an antibonding orbital of the imidazolidinone carbonyl group. This n→π* electron delocalization prevents structural distortion during chromophore excitation that could otherwise lead to fluorescence quenching. In addition, this interaction is present in on-pathway intermediates leading to the chromophore, and thus could direct its biogenesis. Accordingly, this n→π* interaction merits inclusion in computational and photophysical analyses of the chromophore, and in speculations about the molecular evolution of fluorescent proteins.     

A conserved domain in arthropod cuticular proteins binds chitin

Many insect cuticular proteins include a 35-36 amino acid motif known as the R&R consensus. The extensive conservation of this region led to the suggestion that it functions to bind chitin. Provocatively, it has no sequence similarity to the well-known cysteine-containing chitin-binding domain found in chitinases and some peritrophic membrane proteins. Using fusion proteins expressed in E. coli, we show that an extended form of the R&R consensus from proteins of hard cuticles is necessary and sufficient for chitin binding. Recombinant AGCP2b, a putative cuticular protein from the mosquito Anopheles gambiae, was expressed in E. coli and the purified protein shown to bind to chitin beads. A stretch of 65 amino acids from AGCP2b, including the R&R consensus, conferred chitin binding to glutathione-S-transferase (GST). Directed mutagenesis of some conserved amino acids within this extended R&R consensus from hard cuticle eliminated chitin binding. Thus arthropods have two distinct classes of chitin binding proteins, those with the chitin-binding domain found in lectins, chitinases and peritrophic membranes (cysCBD) and those with the cuticular protein chitin-binding domain (non-cysCBD).     

A conserved helix-unfolding motif in the naturally unfolded proteins

Among the naturally unfolded proteins there are many polypeptides that retain an extended conformation in the absence of any apparent signal. Using sequence alignment and secondary structure prediction tools, a conserved (LS/SL)(D/E)(D/E)(D/E)X(E/D) motif is uncovered in the vicinity of the N-terminus of their unfolded helices. A comparison of these data with published observations allows one to propose that the (LS/SL)(D/E)(D/E)(D/E)X(E/D) motif is a helix-unfolding signal. Furthermore, the strong similarity between this motif and the STXXDE casein kinase II phosphorylation site suggests a regulatory mechanism for the naturally unfolded proteins within the cell.     

Actin-binding proteins are conserved from slime molds to man

DNA clones encoding the actin-binding proteins alpha-actinin and severin from Dictyostelium discoideum were isolated and sequenced. Comparisons of the deduced amino acid sequences with proteins from other species showed striking similarities at distinct regions. The F-actin cross-linking molecule alpha-actinin carries two characteristic EF-hand structures highly homologous to the Ca2+-binding loops of proteins from the calmodulin superfamily. An N-terminal region that is conserved in alpha-actinin from D. discoideum and vertebrates is also related to parts of the dystrophin sequence and might represent the F-actin binding site. Severin, gelsolin, villin, and fragmin share homologous sequences that are believed to participate in the severing activity of these proteins.     

Cloning of rabbit uricase cDNA reveals a conserved carboxy-terminal tripeptide in three species

cDNA clones encoding uricase have been isolated from a rabbit liver cDNA library. The nucleotide sequences of the cDNAs have been determined and those of the rat uricase cDNA have been revised. In all three uricases, the carboxy-terminal tripeptides are Ser-Arg/Lys-Leu sequences, which have recently been suggested as an essential element of peroxisomal targetting signals for many but not all peroxisomal proteins.     

In vitro transport of membrane proteins to peroxisomes by shuttling receptor Pex19p

The peroxin Pex19p comprising 299 amino acids functions in peroxisomal membrane assembly. We here developed a cell-free system for transport of membrane proteins to peroxisomes. Pex19p interacts with multiple membrane peroxins, including other membrane biogenesis peroxins, Pex16p and Pex26p, involved in matrix protein import. Cell-free synthesized, 35S-labeled Pex19p was targeted to subcellular fractions containing peroxisomes from Chinese hamster ovary-K1 cells as well as peroxisomes isolated from rat liver in an ATP-dependent manner. Such translocation was also reproduced with in vitro synthesized 35S-Pex16p with two transmembrane segments and C-tail anchor-type 35S-Pex26p, upon incubation with 35S-Pex19p in the reaction mixtures containing isolated peroxisomes. The transported 35S-Pex16p and 35S-Pex26p were integrated into membranes as assessed by the sodium carbonate extraction method. Peroxisome-associated and partly Na2CO3-resistant 35S-Pex19p was released to the cytosolic fraction upon incubation in the absence of ATP, whereas 35S-Pex16p and 35S-Pex26p remained in the membranes. Furthermore, not only 35S-Pex19p but also 35S-Pex19p complexes each with 35S-Pex16p and 35S-Pex26p were bound to 35S-Pex3p in vitro. Together, these results strongly suggested that Pex19p translocates the membrane peroxins from the cytosol to peroxisomes in an ATP- and Pex3p-dependent manner and then shuttles back to the cytosol.